Role of tumor cell apoptosis in tumor antigen migration to the draining lymph nodes

Establishment of an immune response against cancer may depend on the capacity of dendritic cells to transfer tumor Ags into T cell-rich areas. To check this possibility, we used a colon cancer cell variant that yields tumors undergoing complete T cell-dependent rejection when injected into syngeneic rats. We previously demonstrated that immunogenicity of these tumors depended on the early apoptosis of a part of these tumor cells. In this paper we show that fluorescent tumor cell proteins are released from FITC-labeled tumor cells and undergo engulfment by tumor-infiltrating monocytes without a phenotype of mature dendritic cells or macrophages. Fluorescence-labeled mononuclear cells with a phenotype of MHC class II+ dendritic cells are also found in the T cell areas of the draining lymph nodes. Interestingly, no fluorescent cell can be found in lymph nodes after a s.c. injection of Bcl2-transfected apoptosis-resistant tumor cells that yielded progressive tumors. Proliferation of tumor-immune T lymphocytes was induced by dendritic cells isolated from the draining lymph nodes recovered after a s.c. injection of apoptosis-sensitive, but not apoptosis-resistant, tumor cells. These results show that tumor cell apoptosis releases proteins that are engulfed by inflammatory cells in the tumor, then transported to lymph node T cell areas where they can induce a specific immune response leading to tumor rejection.     

Tumor-specific CD4+ T cells render the tumor environment permissive for infiltration by low-avidity CD8+ T cells

CD4+ T cells enhance tumor destruction by CD8+ T cells. One benefit that underlies CD4+ T cell help is enhanced clonal expansion of newly activated CD8+ cells. In addition, tumor-specific CD4+ help is also associated with the accumulation of greater numbers of CD8+ T cells within the tumor. Whether this too is attributable to the effects of help delivered to the CD8+ cells during priming within secondary lymphoid tissues, or alternatively is due to the action of CD4+ cells within the tumor environment has not been examined. In this study, we have evaluated separately the benefits of CD4+ T cell help accrued during priming of tumor-specific CD8+ T cells with a vaccine, as opposed to the benefits delivered by the presence of cognate CD4+ cells within the tumor. The presence of CD4+ T cell help during priming increased clonal expansion of tumor-specific CD8+ T cells in secondary lymphoid tissue; however, CD8+ T cells that have low avidity for tumor Ag were inefficient in tumor invasion. CD4+ T cells that recognized tumor Ag were required to facilitate accumulation of CD8+ T cells within the tumor and enhance tumor lysis during the acute phase of the response. These experiments highlight the ability of tumor-specific CD4+ T cells to render the tumor microenvironment receptive for CD8+ T cell immunotherapy, by facilitating the accumulation of all activated CD8+ T cells, including low-avidity tumor-specific and noncognate cells.     

A novel immunoregulatory axis of NKT cell subsets regulating tumor immunity

There are many mechanisms that regulate and dampen the immune response to cancers, including several types of regulatory T cells. Besides the T reg cell, we have identified another immunoregulatory circuit initiated by NKT cells that produce IL-13 in response to tumor growth and this IL-13 then induces myeloid cells to make TGF-beta that inhibits cytotoxic T cell-mediated tumor immunosurveillance in several mouse tumor models. This finding created a paradox in the role of NKT cells in tumor immunity, in that they can also contribute to protection. We resolve this paradox by the finding that the suppressive NKT cell is a type II NKT cell that lacks the canonical invariant T cell receptor, whereas the protective cell is a type I NKT cell that expresses the invariant receptor. Further, we see that these two subsets of NKT cells counter-regulate each other, defining a new immunoregulatory axis. The balance along this axis may determine the outcome of tumor immunosurveillance as well as influence the efficacy of anti-cancer vaccines and immunotherapy.     

肿瘤患者CD8+T细胞中CD28表达的研究进展

CD28与B7结合形成的共刺激信号是T细胞激活的第二信号,肿瘤患者CD8^＋T细胞上CD28分子在肿瘤免疫中发挥着重要作用。人体抗肿瘤免疫主要由CD8^＋T细胞介导,根据CD28的表达与否可将CD8^＋T细胞分为细胞毒T细胞（CD8^＋CD28^＋,CTL）和抑制性T细胞（CD8^＋C28^-,Ts）。CTL是体内杀伤肿瘤细胞的主要功能性细胞之一,当该细胞与肿瘤接触时,通过共刺激信号而被激活,发挥其对肿瘤细胞的杀伤作用;Ts在机体的免疫耐受中发挥作用。现就肿瘤患者CD8^＋T细胞上CD28的表达作一综述。     

Differential activation of cytotoxic and suppressor T cells against syngeneic tumors in the mouse.

The cytotoxic T cell against a methylcholanthrene-induced sarcoma, S1509a, was induced in syngeneic mice by deliberate immunization with mitomycin C (MMC)-treated live tumor cells. The soluble tumor antigen (STA) extracted from the same tumor by 3 M KCl was, however, unable to induce the cytotoxic T cell upon immunization, although it was able to activate predominantly the suppressor T cell that then specifically suppressed the effect of the cytotoxic T cell against the homologous tumor. The suppressor T cell generated by STA had the same characteristics as those found in tumor-bearing animals: 1) The suppressor T cell has a very strict specificity against individual tumors; 2) The cell expresses cell surface determinants controlled by genes in the I-J subregion of the mouse H-2 complex. The activity of the cytotoxic T cell was completely inhibited by live tumor cells but not by STA, whereas that of the suppressor T cell was neutralized by STA. The results that cytotoxic and suppressor T cells are activated under different conditions, and that the antigenic determinants recognizable by these two cell types are not the same. The soluble extract contains only the determinants recognizable by the suppressor T cell, and the cytotoxic T cell can be activated only by the determinants associated with self antigen present on the surface of live tumor cells.     

Specific lysis of human tumor cells by T cells coated with anti-T3 cross-linked to anti-tumor antibody

Heteroaggregates containing anti-T3 cross-linked to anti-target cell antibodies have been shown to cause human T cells to lyse target cells that express antigens recognized by the anti-target cell antibody. In this study, we test targeted human T cells for the ability to lyse human tumor cells as a first step toward the application of this phenomenon to tumor immunotherapy. Several monoclonal anti-human tumor antibodies were assayed for binding to a number of human tumor lines and for the ability to promote specific tumor cell lysis when cross-linked with anti-T3. We found that anti-T3 cross-linked to anti-tumor monoclonal antibodies caused cloned human T cells and fresh peripheral blood T cells to lyse the tumor cells with the same specificity as predicted by the binding studies. Peripheral blood T cells were then tested in the presence of various heteroaggregates for the ability to lyse single cell suspensions prepared from fresh tumor or fresh normal tissue. These studies showed that heteroaggregates containing anti-T3 cross-linked to anti-tumor antibody cause fresh human T cells to specifically lyse fresh tumor cells, but not (with one exception) fresh normal cells.     

Human CD4+ effector memory T cells persisting in the microenvironment of lung cancer xenografts are activated by local delivery of IL-12 to proliferate, produce IFN-gamma, and eradicate tumor cells

The implantation of small pieces of human primary lung tumor biopsy tissue into SCID mice results in a viable s.c. xenograft in which the tissue architecture, including tumor-associated leukocytes, tumor cells, and stromal cells, is preserved in a functional state. By monitoring changes in tumor volume, gene expression patterns, cell depletion analysis, and the use of function-blocking Abs, we previously established in this xenograft model that exogenous IL-12 mobilizes human tumor-associated leukocytes to kill tumor cells in situ by indirect mechanisms that are dependent upon IFN-gamma. In this study immunohistochemistry and FACS characterize the early cellular events in the tumor microenvironment induced by IL-12. By 5 days post-IL-12 treatment, the constitutively present human CD45(+) leukocytes have expanded and infiltrated into tumor-rich areas of the xenograft. Two weeks post-treatment, there is expansion of the human leukocytes and complete effacement of the tumor compared with tumor progression and gradual loss of most human leukocytes in control-treated xenografts. Immunohistochemical analyses reveal that the responding human leukocytes are primarily activated or memory T cells, with smaller populations of B cells, macrophages, plasma cells, and plasmacytoid dendritic cells capable of producing IFN-alpha. The predominant cell population was also characterized by FACS and was shown to have a phenotype consistent with a CD4(+) effector memory T cell. We conclude that quiescent CD4(+) effector memory T cells are present within the tumor microenvironment of human lung tumors and can be reactivated by the local and sustained release of IL-12 to proliferate and secrete IFN-gamma, leading to tumor cell eradication.     

Suppression of antitumor immunity by IL-10 and TGF-beta-producing T cells infiltrating the growing tumor: influence of tumor environment on the induction of CD4+ and CD8+ regulatory T cells

We examined the hypothesis that a failure of the immune system to eradicate tumors is due to the immunosuppressive environment created by the growing tumor, which is influenced by the site of tumor growth. We demonstrated that T cell responses to a bystander Ag in mice were suppressed by a growing CT26 tumor. T cells purified from the growing tumor expressed mRNA for IL-10, TGF-beta, and Foxp3. Intracellular cytokine staining revealed a high frequency of IL-10-secreting macrophages, dendritic cells, and CD4+ and CD8+ T cells infiltrating the tumor. In contrast, T cell IFN-gamma production was weak and CD8+ CTL responses were undetectable in mice with CT26 lung metastases and weak and transient following s.c. injection of CT26 cells, but were enhanced in the presence of anti-IL-10 and anti-TGF-beta. Consistent with this, removal of CD8+ T cells abrogated CTL responses and promoted progression of the s.c. tumor. However, in the lung model, depletion of CD8+ T cells significantly reduced the tumor burden. Furthermore, depletion of CD4+ or CD25+ T cells in vivo reduced tumor burden in s.c. and lung models, and this was associated with significantly enhanced IFN-gamma production by CD8+ T cells. These findings suggest that tumor growth facilitates the induction or recruitment of CD4+ regulatory T cells that secrete IL-10 and TGF-beta and suppress effector CD8+ T cell responses. However, CD8+ T regulatory cells expressing IL-10 and TGF-beta are also recruited or activated by the immunosuppressive environment of the lung, where they may suppress the induction of antitumor immunity.     

Alpha 3 domain mutants of peptide/MHC class I multimers allow the selective isolation of high avidity tumor-reactive CD8 T cells

The goal of adoptive T cell therapy in cancer is to provide effective antitumor immunity by transfer of selected populations of tumor Ag-specific T cells. Transfer of T cells with high TCR avidity is critical for in vivo efficacy. In this study, we demonstrate that fluorescent peptide/MHC class I multimeric complexes incorporating mutations in the alpha3 domain (D227K/T228A) that abrogate binding to the CD8 coreceptor can be used to selectively isolate tumor Ag-specific T cells of high functional avidity from both in vitro expanded and ex vivo T cell populations. Sorting, cloning, and expansion of alpha3 domain mutant multimer-positive CD8 T cells enabled rapid selection of high avidity tumor-reactive T cell clones. Our results are relevant for ex vivo identification and isolation of T cells with potent antitumor activity for adoptive T cell therapy.     

Characteristics of the immature cells involved in T cell-mediated enhancement of syngeneic tumor growth.

Enhancement of tumor growth was observed when non-sensitized thymocytes were injected together with tumor cells into syngeneic mice, although this tumor enhancement was less pronounced than that caused by tumor-sensitized T lymphocytes. The cells within the thymus which are responsible for this tumor enhancement were found to be rapidly dividing and to be absent from the thymus a day after cortisone administration. At a longer time interval the cortison-depleted thymus was repopulated by dividing cells which exhibited tumor-enhancing reactivity. The characteristics of these cells suggest that they are in the early stages of thymic processing. The enhancing thymocytes were sensitive to treatment with the thymic humoral factor which functions in T cell maturation, and their enhancing activity was cancelled by such treatment. These results are compatible with our hypothesis that exposure of immature T cells to a tumor stimulus may lead to tumor enhancement whereas interaction between mature T lymphocytes and tumor cells may be required for tumor inhibition.     

Improving Antigenic Peptide Vaccines for Cancer Immunotherapy Using a Dominant Tumor-specific T Cell Receptor

Vaccines that incorporate peptide mimics of tumor antigens, or mimotope vaccines, are commonly used in cancer immunotherapy and function by eliciting increased numbers of T cells that cross-react with the native tumor antigen. Unfortunately, they often elicit T cells that do not cross-react with or that have low affinity for the tumor antigen. Using a high affinity tumor-specific T cell clone, we identified a panel of mimotope vaccines for the dominant peptide antigen from a mouse colon tumor that elicits a range of tumor protection following vaccination. The TCR from this high affinity T cell clone was rarely identified in ex vivo evaluation of tumor-specific T cells elicited by mimotope vaccination. Conversely, a low affinity clone found in the tumor and following immunization was frequently identified. Using peptide libraries, we determined if this frequently identified TCR improved the discovery of efficacious mimotopes. We demonstrated that the representative TCR identified more protective mimotopes than the high affinity TCR. These results suggest that targeting a dominant fraction of tumor-specific T cells generates potent immunity and that consideration of the available T cell repertoire is necessary for targeted T cell therapy. These results have important implications when optimizing mimotope vaccines for cancer immunotherapy.     

Divergent roles for CD4+ T cells in the priming and effector/memory phases of adoptive immunotherapy

The requirement for CD4(+) Th cells in the cross-priming of antitumor CTL is well accepted in tumor immunology. Here we report that the requirement for T cell help can be replaced by local production of GM-CSF at the vaccine site. Experiments using mice in which CD4(+) T cells were eliminated, either by Ab depletion or by gene knockout of the MHC class II beta-chain (MHC II KO), revealed that priming of therapeutic CD8(+) effector T cells following vaccination with a GM-CSF-transduced B16BL6-D5 tumor cell line occurred independently of CD4(+) T cell help. The adoptive transfer of CD8(+) effector T cells, but not CD4(+) effector T cells, led to complete regression of pulmonary metastases. Regression of pulmonary metastases did not require either host T cells or NK cells. Transfer of CD8(+) effector T cells alone could cure wild-type animals of systemic tumor; the majority of tumor-bearing mice survived long term after treatment (>100 days). In contrast, adoptive transfer of CD8(+) T cells to tumor-bearing MHC II KO mice improved survival, but eventually all MHC II KO mice succumbed to metastatic disease. WT mice cured by adoptive transfer of CD8(+) T cells were resistant to tumor challenge. Resistance was mediated by CD8(+) T cells in mice at 50 days, while both CD4(+) and CD8(+) T cells were important for protection in mice challenged 150 days following adoptive transfer. Thus, in this tumor model CD4(+) Th cells are not required for the priming phase of CD8(+) effector T cells; however, they are critical for both the complete elimination of tumor and the maintenance of a long term protective antitumor memory response in vivo.     

An unexpected role for p53 in augmenting SV40 large T antigen-mediated tumorigenesis

Simian virus 40 large T antigen transforms cells by sequestration and inactivation of the tumor suppressor proteins p53, retinoblastoma gene product (pRb), and the pRb-related proteins p107 and p130. Thus, the absence of functional p53 is expected to promote T antigen-mediated tumorigenesis. However, in a transgenic mouse model of T antigen-mediated beta cell carcinogenesis (Rip1Tag2), tumor volumes are significantly diminished when these mice are intercrossed with p53-deficient mice. Whereas the incidence of beta tumor cell apoptosis is unaffected, their proliferation rate is reduced in p53-deficient beta cell tumors in vivo and in cell lines established from these tumors in vitro. Biochemical analyses reveal higher levels of T antigen in wild-type tumor cells as compared to p53-deficient tumor cells. The data indicate that p53 stabilizes SV40 large T antigen, thereby augmenting its oncogenic potential as manifested by increased proliferation rates in wild-type beta tumor cells as compared to p53-deficient beta tumor cells.     

Tumor-specific CD4+ T cells have a major "post-licensing" role in CTL mediated anti-tumor immunity

A number of tumor studies have indicated a link between CD4 help and the magnitude and persistence of CTL activity; however, the mechanisms underlying this have been largely unclear. To evaluate and determine the mechanisms by which CD4(+) T cells synergize with CD8(+) T cells to prevent tumor growth, we used the novel technique of monitoring in vivo CTL by labeling target cells with CFSE. This approach was supported by the direct visualization of CTL using peptide-MHC tetramers to follow tumor-specific T cells. The data presented demonstrate that while cotransfer of Ag-specific CD4(+) T cells was not required for the generation of CTLs, because adoptive transfer of CD8(+) T cells alone was sufficient, CD4(+) T cells were required for the maintenance of CD8(+) T cell numbers. Our data suggest that there is a correlation among the number of CD8(+) T cells, in vivo CTL function, and IFN-gamma production, with no evidence of a partial or nonresponsive phenotype among tetramer-positive cells. We also show that CD4(+) T cells are required for CD8(+) T cell infiltration of the tumor.     

How regulatory CD25(+)CD4(+) T cells impinge on tumor immunobiology? On the existence of two alternative dynamical classes of tumors

Aiming to get a better insight on the impact of regulatory CD25(+)CD4(+) T cells in tumor immunobiology, a simple mathematical model was formulated and studied. This model is an extension of a previous model for the dynamics of autoreactive regulatory cells and effector cells that interact upon their co-localized activation at the antigen presenting cells (APCs). It assumes that tumor growth stimulates the activation and migration to the adjacent lymph node of fresh APCs loaded with tumor antigens. These APCs stimulate the growth of both effector and regulatory T cells, which may then migrate to the tumor site and induce tumor cell destruction. Our results predict the existence of two alternative dynamic modes of unbounded tumor growth. In the first mode, the tumor induces the expansion of effector T cells that outcompete regulatory T cells, but nevertheless fail to control the tumor. In the second mode, the tumor induces a balanced expansion of both effector and regulatory T cells, which prevents the tumor from being destroyed by the immune cells. Tumors characterized by a high specific growth rate, low immunogenicity, and that are relatively resistant to T cell destructive functions, will grow in the first mode; conversely, tumors that have a slow specific growth rate, that are immunogenic, and/or that are more sensitive to destruction by T cells will grow in the second mode. Overall, this result provides a simple explanation to the fact that the development of some tumors expands regulatory T cells while others do not, predicting how some key dynamical properties of the tumor determine either one or the other type of behavior.     

Tumor reactivity of immune T cells in short-term culture

 The adoptive transfer of immune T cells is capable of mediating the regression of established neoplasms in a variety of animal tumor models. The antitumor activity is invariably proportional to the number of cells transferred, thus methods to expand immune cell number while maintaining therapeutic efficacy have been extensively investigated. Here we demonstrate that a short-term culture of immune T cells can amplify the T cell number and enhance the therapeutic reactivity against established pulmonary tumor, while maintaining immunological specificity. In contrast, the therapeutic reactivity of immune T cells against established subcutaneous tumor is diminished by short-term culture. While cultured immune T cells are not cytotoxic in a 4-h Cr-release assay, they do specifically secrete interferon γ upon stimulation with tumor cells. T cells cultured after a single exposure to tumor are even more active against pulmonary tumor than T cells cultured from mice immunized repeatedly. This culture system can rapidly induce T cell proliferation and differentiation into mature effector cells, and the resulting cells demonstrate an enhanced ability to treat visceral metastases, but a decreased ability to treat subcutaneous tumor. Thus T cells cultured after a single exposure to tumor represent an ideal population of cells for use in human adoptive immunotherapy trials. Received: 18 July 1996 / Accepted: 27 September 1996     

T cell immunity induced by live, necrotic, and apoptotic tumor cells

The rules that govern the engagement of antitumor immunity are not yet fully understood. Ags expressed by tumor cells are prone to induce T cell tolerance unless the innate immune system is activated. It is unclear to what extent tumors engage this second signal link by the innate immune system. Apoptotic and necrotic (tumor) cells are readily recognized and phagocytosed by the cells of the innate immune system. It is unknown how this affects the tumor's immunogenicity. Using a murine melanoma (B16m) and lymphoma (L5178Y-R) model, we studied the clonal sizes and cytokine signatures of the T cells induced by these tumors in syngeneic mice when injected as live, apoptotic, and necrotic cells. Both live tumors induced a type 2 CD4 cell response characterized by the prevalent production of IL-2, IL-4, and IL-5 over IFN-gamma. Live, apoptotic, and necrotic cells induced CD4 (but no CD8) T cells of comparable frequencies and cytokine profiles. Therefore, live tumors engaged the second signal link, and apoptotic or necrotic tumor cell death did not change the magnitude or quality of the antitumor response. A subclone of L5178Y-R, L5178Y-S cells, were found to induce a high-frequency type 1 response by CD4 and CD8 cells that conveyed immune protection. The data suggest that the immunogenicity of tumors, and their characteristics to induce type 1 or type 2, CD4 or CD8 cell immunity is not primarily governed by signals associated with apoptotic or necrotic cell death, but is an intrinsic feature of the tumor itself.     

Requirement of monocytes and T-helper cells during development of tumor cell cytotoxicity in targeted T cells

In cocultures of human plancental alkaline phosphatase(PLAP)-positive MO₄ tumor cells and human peripheral blood mononuclear cells (PBMC), also containing a heteroconjugate (7E8-OKT3) synthesized between the anti-PLAP monoclonal antibody 7E8 and the anti-CD3 antibody OKT3, and supplemented with low levels of recombinant interleukin-2 (rIL-2), T cells are progressively activated, resulting in tumor cell lysis. To unravel the contribution of PBMC subsets to the generation of this targetable cytotoxicity, PBMC subsets were studied after their isolation by cell sorting, either from fresh PBMC or from PBMC peractivated with OKTe3 and rIL-2. Whereas no targetable cytotoxicity was found in Fc-receptor-bearing CD3-cells, tumor cells were lysed by CD3⁺ T cells (mostly CD8⁺) isolated from pre-activated PBMC. When isolated from fresh PBMC, neither the CD8⁺ T cell subset, nor the total CD3⁺ T cell population developed significant targetable cytotoxicity, even in the presence of rIL-2. Thus, additional cell types are essential for the CD8⁺ T cell activation. Indeed. CD4⁺ T cells isolated from pre-activated but not from fresh PBMC were capable of eliciting cytotoxicity in fresh CD8⁺ T cells. The non-targeted monocytes were found to be the activators of the CD4⁺ T cells. In summary, targeting T cells to the surface of a tumor cell is not sufficientper se to achieve activation and lysis. The progressive tumor cell lysis by targeted T cells seems to be initiated by non-targeted monocytes activating CD4⁺ T cells, these cells in turn promoting CD8⁺ T cell activation, necessary for the development of cytotoxicity.     

Development of antigen-specific CD8+ CTL in MHC class I-deficient mice through CD4 to CD8 conversion

CD8+ CTL are the predominant tumoricidal effector cells. We find, however, that MHC class I-deficient mice depleted of CD8+ T cells are able to mount an effective antitumor immunity after immunization with fused dendritic/tumor cells. Such immunity appears to be mediated by the generation of phenotypic and functional CD8+ CTL through CD4+ to CD8+ conversion, which we have demonstrated at the single cell level. CD4+ to CD8+ conversion depends on effective in vivo activation and is promoted by CD4+ T cell proliferation. The effectiveness of this process is shown by the generation of antitumor immunity through adoptive transfer of primed CD4 T cells to provide protection against tumor cell challenge and to eliminate established pulmonary metastases.     

Use of the allogeneic TCR repertoire to enhance anti-tumor immunity

It is well established that antigen-specific T lymphocytes can inhibit tumor growth in humans and in mice, leading to complete tumor elimination in some cases. However, in many cases T cell immunity is unable to successfully control tumor progression. Since tumors are derived from normal tissues, most antigens are shared with normal tissues, although expression levels are usually elevated in malignant cells. Nevertheless, low-level expression in normal cells can be sufficient to render autologous T cells tolerant and thus unable to mount effective immune responses against tumors. Here, we review how allogeneic T cells can be used to isolate T cells that effectively recognise and kill tumor cells, but not normal cells with low level of antigen expression. The TCR of allogeneic T cells can be introduced into patient T cells to equip them with anti-tumor specificity that may not be present in the autologous T cell repertoire.