Retroviral transduction of interferon-γ cDNA into a nonimmunogenic murinefibrosarcoma: generation of T cells in draining lymph nodes capable of treating established parental metastatic tumor

Gene modification of tumor cells with the cDNA for interferon (IFN) has been shown to increase the immunogenicity of some tumor cells. In order to explore further the possible therapeutic relevance of these previous findings, two clones of the nonimmunogenic MCA-102 fibrosarcoma of C57BL/6 origin were retrovirally transduced with the cDNA encoding murine IFN: 102.4JK (4JK), a clone with relatively high major histocompatibility complex (MHC) class I expression, and 102.24JK (24JK), a clone with low expression of surface MHC class I molecules. Retroviral transduction of tumor cells with the cDNA encoding for IFN resulted in a substantial up-regulation of MHC class I surface expression in the 24JK clone but little change of class I in the 4JK clone. In an attempt to generate antitumor lymphocytes, these gene-modified cells were inoculated into mouse footpads and draining lymph nodes (DLN) were removed, dispersed, and cultured in vitro for 10 days with irradiated tumor cells and interleukin-2. DLN from mice bearing either unmodified tumor or tumor transduced with cDNA encoding neomycin resistance (Neo ^R) or IFN, were used to treat recipients harboring 3-day pulmonary metastases induced by the parental, unmodified tumor. Treatment with DLN cells obtained following the injection of 24JK tumor cells modified with the gene for IFN significantly reduced the number of pulmonary metastases in four separate experiments, compared to groups treated by DLN cells generated from inoculation of either the unmodified, parental 24JK clone or the same clone transduced with theNeo ^R gene only. In contrast, DLN cells induced either by IFN-transduced 4JK (high expression of MHC class I) or an unmodified 4JK tumor (moderate expression of MHC class I) had significant but equal therapeutic efficacy. Although the in vitro growth rate of tumor cell lines was unaffected by the insertion of the mouse IFN cDNA, their in vivo (s.c.) growth rates were significantly slower than those of the nontransduced tumors. Thus, after retroviral transduction of the murine IFN cDNA into a nonimmunogenic tumor with a very low level of surface expression of MHC class I, modified tumor cells could elicit therapeutic T cells from DLN capable of successfully treating established pulmonary metastases upon adoptive transfer. This strategy significantly confirms previous observations on the potential therapeutic effects of gene modification of tumor cells with IFN and extends the realm of therapeutic possibilities to include the use of DLN cells for the development of T-cell based immunotherapies against nonimmunogenic human tumors.     

Recognition of neuroectodermal tumors by melanoma-specific cytotoxic T lymphocytes: evidence for antigen sharing by tumors derived from the neural crest

Melanomas from different patients have been shown to express shared tumor antigens, which can be recognized in the context of the appropriate MHC class 1 molecules by cytolytic T cells. To determine if T-cell-defined melanoma antigens are expressed on other tumors of neuroectodermal origin, four melanoma-specific cytotoxic T lymphocyte (CTL) cultures derived from tumor-infiltrating lymphocytes (TIL) were tested for lysis of a panel of 23 HLA-A2⁺ neuroectodermal tumor cell lines of various histologies, including retinoblastoma (1), neuroblastoma (8), neuroepithelioma (6), astrocytoma (2), neuroglioma (1), and Ewing's sarcoma (5). Low expression of MHC class I and/or ICAM-1 molecules was found on 22 of 23 neuroectodermal tumor lines, and could be enhanced by treatment with interferon (IFN). Following IFN treatment, three Ewing's sarcoma lines were lysed by at least one melanoma TIL culture, and levels of lysis were comparable to melanoma lysis by these TIL. Lysis could be inhibited by monoclonal antibodies directed against MHC class I molecules and against CD3, indicating specific immune recognition of tumor-associated antigens. None of the other neuroectodermal tumors tested were lysed by TIL, but they could be lysed by non-MHC-restricted lymphokine-activated killer cells. This demonstration of immunological cross-reactivity between melanomas and Ewing's sarcomas, two tumors of distinct histological types with a common embryonic origin, has implications for the developmental nature of these CTL-defined tumor antigens. It also raises the possibility that specific antitumor immunotherapies, such as vaccines, may be reactive against more than one form of cancer.     

The selection of tumor variants with altered expression of classical and nonclassical MHC class I molecules: implications for tumor immune escape

Tumor immune escape variants can be identified in human and experimental tumors. A variety of different strategies are used by tumor cells to avoid recognition by different immune effector mechanisms. Among these escape routes, alteration of MHC class I cell surface expression is one of the mechanisms most widely used by tumor cells. In this review we focus our attention on the T-cell immune selection of MHC class I–deficient tumor variants. Different altered MHC class I phenotypes that originate from multiple molecular mechanisms can be identified in human tumors. MHC-deficient tumor clones can escape T-cell immune responses, but are in theory more susceptible to NK-cell–mediated lysis. In this context, we also review the controversial issue of the aberrant expression of nonclassical HLA class I molecules, particularly HLA-G, in tumors. This expression may be relevant in tumor cells that have lost the capacity to interact with NK inhibitory receptors—namely, those tumor cells with no HLA-B or HLA-C expression. Most published studies have not analyzed these possibilities and do not provide information about the complete HLA-A, HLA-B, or HLA-C molecule profiles of the tumors studied. In contrast, HLA-E has been reported to be expressed in some tumor cell lines with very low HLA-A, HLA-B, and HLA-C expression, suggesting that HLA-E may indeed, in some cases, play a role by inhibiting NK lysis of cells that otherwise would be destroyed by NK cells. Finally, we provide evidence that the status of the immune system in the tumor-bearing animal is capable of defining the MHC profile of the tumor cells. In other words, MHC class I–negative metastatic colonies are produced in immunocompetent animals, and MHC class I–positive colonies in T-cell immunodeficient individuals.This article forms part of the Symposium in Writing Tumor escape from the immune response, published in Vol. 53.     

Immunization with mutagen-treated (tum−) cells causes rejection of nonimmunogenic rat glioma isografts

The ethyl-N-nitrosourea-induced rat glioma N32 was treated with the mutagenic compoundN-methyl-N-nitro-N-nitrosoguanidine and the surviving cells cloned by limiting dilution. Out of 20 clones tested 8 did not produce tumors subcutaneously even after challenge doses 3 log units above the minimal tumor dose for N32. All of 5 clones grew in a retarded manner intracerebrally but produced tumors in some animals. Preimmunizations with three of the rejected clones (tum^–) gave protection against subcutaneous and intracerebral isografts of the unmutated N32. This effect could be enhanced if the cells used for immunizations were pretreated with interferon (IFN) for 48 h. If immunizations were started subsequent to challenge, only immunization with one of two tested tum^– clones pretreated with IFN induced significant rejection against intracerebral N32 isografts. Both N32 and its tum^– closes were MHC class I positive and MHC class II negative. IFN treatment enhanced the MHC class I expression with 20%–90% on the tum^– clones and with 40% on N32. MHC class II expression could be induced on N32 cells after 7 days of IFN treatment but not on any of the tum^– clones tested. We conclude that the enhancing effect of IFN treatment on tumor isograft rejection may depend on up-regulation of MHC class I but not of MHC class II. This investigation demonstrates that it is possible to induce rejection of weakly immunogenic intracerebral brain tumors by immunization with selected highly immunogenic tumor cell mutants. In conjunction with relevant cytokines, the cross-protective effect of these tum^– variants might be further enhanced and serve as a model for immunotherapy against malignant human brain tumors.     

Introduction of the interferon γ gene into mouse T lymphoma cells with low MHC class I-expression results in selective induction of H-2Dk and concomitant enhanced metastasis

 Interferon-γ(IFNγ)-induced up-regulation of MHC class I expression on tumor cells can induce a potent CD8-mediated antitumor response. Consequently, many investigators have proposed IFNγ gene transfection as a means to immunogenize tumor cells and to vaccinate against metastatic disease. In this study, we demonstrate that transfection of the IFNγ gene in a BW5147 variant (LiD^lo) with low MHC class I expression results in a selective induction of H-2D^k but unaltered H-2K^k expression. In earlier reports we demonstrated a positive correlation between H-2D^k expression and enhanced metastatic potential of BW variants. In accordance with these observations, we observed that intravenous inoculation of LiD^lo(IFNγ) variants into syngeneic AKR mice led to enhanced metastasis as compared to parental LiD^lo and LiD^lo(neo) control transfectants. Tumor cells, derived from local subcutaneous tumors or sporadic metastases from mice inoculated with LiD^lo tumor cells, were found to up-regulate H-2D^k selectively. Anti-asialoGM1 treatment of AKR mice allowed rapid experimental metastasis formation by the LiD^lo and LiD^lo(neo) variants, indicating that natural killer (NK) cells control the metastatic behavior of these tumor cells. This was corroborated by in vitro cytotoxicity experiments, demonstrating that LiD^lo and LiD^lo(neo) tumor cells were NK-sensitive, while the BW IFNγ transfectants became resistant to lymphokine-activated killer cells and poly(I)·poly(C)-induced NK cells. We thus conclude that (a) IFNγ up-regulates selectively the MHC class I antigen H-2D^k, (b) H-2D^k governs susceptibility towards NK cells, and (c) NK susceptibility determines the experimental metastatic behavior of BW tumor cells. Received: 2 May 1996/Accepted: 21 May 1996     

Inhibition of protein synthesis enhances the lytic effects of tumor necrosis factor α and interferon γ in cell lines derived from gynecological malignancies

Summary Few clinical responses have occurred in preliminary studies using the cytokines tumor necrosis factor (TNF) or interferon (IFN) in cancer patients. This may be related to the observation that many malignant cell lines are resistant to lysis by these cytokinesin vitro. Resistance to lysis by TNF or IFN in many cells is controlled by a protein-synthesis-dependent mechanism, such that when protein synthesis is inhibited cells become sensitive to lysis by these cytokines. Because there is some evidence that TNF and IFN act through different lytic mechanisms and are opposed by different resistance mechanisms, we treated a panel of eight cell lines, five derived from human cervical carcinomas (ME-180, MS751, SiHa, HT-3, and C-33A) and three derived from ovarian carcinomas (Caov-3, SK-OV-3, and NIH: OVCAR-3) with both TNF and IFN to determine whether such combination treatment might maximizein vitro cell lysis. Our results showed that pretreatment with IFN followed by exposure to TNF in the presence of protein synthesis inhibitors increased lysis of seven of the eight cell lines above that seen with either TNF or IFN and inhibitors of protein synthesis. Only the cell line C-33A was resistant to lysis by TNF and IFN, when exposed to these agents both alone and in combination with protein synthesis inhibitors. Clinically, combining the cytokines TNF and IFN with protein synthesis inhibitors may maximize thein vivo lytic effects of these cytokines.Supported by American Cancer Society Career Development Award 90-221     

MHC antigen expression by melanomas recovered from mice treated with allogeneic mouse fibroblasts genetically modified for interleukin-2 secretion and the expression of melanoma-associated antigens

Recent approaches toward the immunotherapy of neoplastic disease involve the introduction of expression-competent genes for interleukin-2 (IL-2) into autologous malignant cells. Treatment of tumor-bearing experimental animals with the IL-2-secreting cells successfully induces partial and at times complete remissions. In most instances, however, although delayed, progressive tumor growth continues. Here, certain of the characteristic of B16 melanomas (H-2^b) persisting in C57BL/6 mice (H-2^b) treated with an IL-2-secreting, melanoma-antigen-positive cellular immunogen (RLBA-IL-2 cells) are described. Unlike the melanoma cells first injected, B16 cells recovered from mice treated with RLBA-IL-2 cells were deficient in the experssion of MHC class I, but not class II determinants. Deficient MHC class I expression correlated with the cells' resistance to cytotoxic T lymphocytes (CTL) from the spleens of mice immunized with RLBA-IL-2 cells. Melanomas persisting in mice treated with non-IL-2-secreting, melanoma-antigen-positive cell constructs (RLBA-ZipNeo cells) were also deficient in the expression of MHC class I determinants, and the melanoma cells were resistant to CTL from mice immunized with RLBA-ZipNeo cells. Thus, the expression of melanoma-associated antigens rather than IL-2-secretion correlated with deficient MHC class I expression by the persistent melanomas. This point was substantiated by the expression of MHC class I antigens by melanomas persisting in mice treated with IL-2-secreting, melanoma-antigen-negative LM cells (LM-IL-2); it was equivalent to that of melanomas in untreated mice. The involvement of MHC class I antigens in the immune resistance of persistent melanoma cells from mice treated with the melanoma-autigen-positive immunogens was indicated by the effect of interferon (IFN) orN-methyl-N-nitro-N-nitrosoguanidine (MNNG) on the susceptibility of the cells to anti-melanoma CTL. Treatment of the resistant melanomas with IFN or MNNG stimulated MHC class I antigen expression and restored the cells' sensitivity to CTL from mice immunized with IL-2-secreting or nonsecreting, melanoma-antigen-positive cellular immunogens. Prior treatment of the treated cells with antibodies to MHC class I determinants inhibited the cells' susceptibility to CTL from mice immunized with RLBA-IL-2 cells.     

Lysis of endothelial cells by autologous lymphokine-activated killer cells

The mechanisms of lysis of endothelial cells derived from human umbilical vein (HUVEC) by autologous lymphokine-activated killer (LAK) cells, generated from cord blood lymphocytes of the same donor, were investigated. Freshly isolated HUVEC as well as HUVEC cultured for several passages were efficiently lysed by autologous LAK cells, and their susceptibility to the LAK cells was almost the some as that of allogenic HUVEC. Complement-depletion experiments revealed that the lysis was mainly dependent on CD16-natural killer (NK) LAK cells. Pretreatment of HUVEC with recombinant interferon (rIFN) for 24 h made them resistant to lysis by autologous LAK cells, while pretreatment with either rIL-1. rTNF, or acidic or basic fibroblast growth factor did not alter the lytic sensitivity of HUVEC. The resistance of rIFN-treated HUVEC was specific to lysis by CD16⁺ NK LAK cells, and their lysis by CD3⁺ T-LAK cells was not significantly altered. Moreover, in comparison with control HUVEC or rIL-1-treated HUVEC, rIFN-treated HUVEC had a significantly less potent inhibitory effect on the lysis of untreated HUVEC, when used as an unlabeled target. This suggests that rIFN treatment may down-regulate the recognition of some molecules on HUVEC by rIL-2-activated NK cells. These data suggest that damage of the endothelium during LAK therapy is mainly dependent on LAK cells with a NK phenotype that can specifically recognize a certain molecule on autologous endothelial cells.     

Interferon-γ-induced increased sensitivity ofHER2/neu-overexpressing tumor cells to lymphokine-activated killer cell lysis: importance of ICAM-1 in binding and post-binding events

Treatment ofHER2/neu-overexpressing target cells with interferon (IFN) (200–2000 U/ml for 3 days) markedly enhances their sensitivity to lymphokine-activated killer (LAK) cell lysis. Increased sensitivity is associated with an up-regulation of intercellular adhesion molecule ICAM-1 determinants and a down-regulation ofHER2/neu expression. In the present study, we show that exposure to another cytokine, tumor necrosis factor (200 U/ml for 3 days), also decreasedHER2/neu expression but had no effect on LAK cell lysis and ICAM-1 expression. This suggests that down-regulation of oncogene expression is not sufficient by itself to induce an enhanced sensitivity to LAK cell lysis. IFN-induced enhanced lysis was associated with an increased binding between effectors and targets, and antibodies to ICAM-1 as well as its counter-receptor LFA-1, blocked the increased binding and lysis. Treatment with IFN still significantly enhanced lysis even when concanavalin A was added to the assay to induce maximal binding, indicating that a post-binding effect also participated in enhanced cytotoxicity. These post-binding alterations, were also sensitive to blocking with anti-ICAM-1 and anti-LFA-1 antibodies. Treatment with IFN also sensitized targets to lysis by T cells in the presence of lectin but had no effect on the relative resistance of HER2⁺ cells to lysis mediated by perforin or TNF. Together these data demonstrate the importance of ICAM-1 determinants in binding and post-binding events in the IFN-induced increased lysis ofHER2/neu ⁺ targets.Supported by research funds of the Veteran's Administration, the California Institute for Cancer Research and Jonsson Cancer Center core grant CA 16042 funded by NIH     

MHC class II and CD80 tumor cell–based vaccines are potent activators of type 1 CD4<Superscript>+</Superscript> T lymphocytes provided they do not coexpress invariant chain

We are developing vaccines that activate tumor-specific CD4⁺ T cells. The cell-based vaccines consist of MHC class I⁺ tumor cells that are genetically modified to express syngeneic MHC class II and costimulatory molecules. Previous studies demonstrated that treatment of mice with established tumors with these vaccines resulted in regression of solid tumors, reduction of metastatic disease, and increased survival time. Optimal vaccines will prime naïve T cells and activate T cells to tumor peptides derived from diverse subcellular compartments, since potential tumor antigens may reside in unique cellular locales. To determine if the MHC class II / costimulatory molecule vaccines fulfill these conditions, the vaccines have been tested for their ability to activate antigen-specific, naïve, transgenic CD4⁺ T lymphocytes. MHC class II⁺CD80⁺ vaccine cells were transfected with hen eggwhite lysozyme targeted to the cytosol, nuclei, mitochondria, or endoplasmic reticulum, and used as antigen-presenting cells to activate I-A^k–restricted, lysozyme-specific CD4⁺ 3A9 transgenic T cells. Regardless of the cellular location of lysozyme, the vaccines stimulated release of high levels of IFN- and IL-2. If the vaccines coexpressed the MHC class II accessory molecule invariant chain, then IFN- and IL-2 release was significantly reduced. These studies demonstrate that in the absence of invariant chain the MHC class II and CD80 tumor cell vaccines (1) function as antigen-presenting cells to activate naïve, tumor-specific CD4⁺ cells to endogenously synthesized tumor antigens; (2) polarize the activated CD4⁺ T cells toward a type 1 response; and (3) present epitopes derived from varied subcellular locales.Abbreviations APC antigen-presenting cells - CIITA MHC class II transactivator - CytoHEL HEL targeted to cytoplasm - ER endoplasmic reticulum - ErHEL HEL targeted to ER - HEL hen eggwhite lysozyme - 3A9 HEL_46–61–specific, I-A^k–restricted TCR - Hph hygromycin - Ii invariant chain - MAb monoclonal antibody - MitoHEL HEL targeted to mitochondria - NucHEL HEL targeted to nucleus - Puro puromycin - TG transgenic - Zeo Zeocin     

Lysis of small cell carcinoma of the lung tumor cell lines by gamma interferon-activated allogeneic peripheral blood mononuclear cells: abrogation of killing by pretreatment of tumor cells with gamma interferon

Summary Interferon has been shown to enhance the ability of nonspecific cytotoxic mononuclear cells to lyse some, but not all, tumor cells. We have examined the effect of recombinant human gamma interferon (rIFN) on the cell-mediated cytolysis of tumor target cells derived from continuously cultured lines of small cell carcinoma of the lung (SCCL). Cells from the SCCL lines DMS 44, 53, 79, 92, and 406 were labeled with ⁵¹Cr and incubated with normal and rIFN-stimulated peripheral blood mononuclear cells for 18 h at 37 °C and tumor cell lysis estimated by measuring ⁵¹Cr release. Although cells from certain SCCL lines were good targets for cell mediated cytotoxicity, susceptibility to lysis was heterogenous among the different SCCL lines. DMS 406 and 79 were, on average, maximally lysed, while DMS 44, 53, and 92 showed less susceptibility to lysis by either control or rIFN-stimulated effector cells. In addition, although pretreatment with rIFN increased the cytolytic capacity of normal peripheral blood mononuclear cells from several different donors, preincubation of the tumor cell lines with rIFN resulted in inhibition of cytolysis mediated by both control and IFN-activated effector cells. These findings suggest that although rIFN may enhance cell-mediated lysis of SCCL tumor cells, it may also decrease susceptibility to lysis.This work was supported by Grants CA 37868, CA 31888, CA31918, CA33852, and AI 19053 awarded by the National Cancer Institute and Institute of Allergy and Infectious Diseases, DHHS. Statistical assistance was provided by Therese Stukel, biostatistician at the Norris Cotton Cancer Center, Hanover, H. H. and supported by Grant CA 23108 from the National Cancer Institute     

Expression of the adhesion molecule ICAM-1 and major histocompatibility complex class I antigens on human tumor cells is required for their interaction with autologous lymphocytes in vitro

Summary In a group of 30 human tumors, comprising 12 lung, 14 ovarian, 2 breast carcinomas, 1 hypernephroma and 1 mid-gut carcinoid, the expression of major histocompatibility complex (MHC) class I molecules and the intercellular adhesion molecule 1 (ICAM-1, CD54) was found to vary independently. Some tumors expressed both or neither of these molecules. Among 9/13 ICAM-1⁺ tumors, in which >50% cells reacted with the anti-ICAM-1 monoclonal antibody (mAb) (LB-2), the class I antigen was also detected on >50% of the cells. Only 2 ICAM-1⁺ tumors were class-I^–. In 5/17 cases the tumors were MHC-class-I⁺ and ICAM-1^–. Lymphocytes collected from the blood or from the tumor site were assayed for recognition on the tumor cells in the auto-tumor cytotoxicity test and in mixed lymphocyte tumor cell culture (MLTC). Positive results were obtained only with the MHC-class-I⁺/ICAM-1⁺ tumors. In vitro treatment of the tumor cell suspensions with interferon and tumor necrosis factor (TNF) induced or enhanced the ICAM-1 and/or class I antigen expression in 8/12 cases. Of the tumor samples treated, 8/9 aquired stimulatory capacity and 3/10 became susceptible to lysis by the lymphocytes. In 6/6 MLTC performed with the cytokine-treated tumor cells, cytotoxicity against the autologous tumor was generated. Three of these MLTC lymphocytes also lysed the untreated targets. mAb directed to class I antigens or to ICAM-1 inhibited both the stimulation by and the lysis of tumor cells when confronted with fresh lymphocytes. The cytotoxicity generated in the MLTC was also inhibited. If, however, the cytotoxic function was induced in MLTC containing interleukin-2 (5 U/ml), inhibition was obtained only by pretreatment of the targets with mAb against ICAM-1. The results show thus (a) that the lymphocytes react in vitro with tumor cells only if these express both MHC class I molecules and ICAM-1; (b) that expression of these molecules can be induced by interferon and TNF; (c) that cytotoxic effectors generated in the MLTC with cytokine-treated tumors can also act on the untreated tumor cells. The requirement of the two surface moieties for the interaction with lymphocytes was also substantiated by blockade with relevant mAb.     

The regulatory role of CD45 on rat NK cells in target cell lysis.

To investigate the role of CD45 in rat NK cell function, we developed new mAbs directed against rat CD45. mAb ANK12 binds to a high molecular isoform of CD45 and mAb ANK74 binds to the common part on all known CD45 isoforms, as has been described for the anti-rat CD45 mAb OX1. The ability of these mAbs to affect NK cell-mediated lysis was tested using the Fc receptor-positive target cell line P815. mAb ANK12 was found to significantly enhance the lysis of P815, whereas ANK74 and the anti-CD45 mAb OX1 did not. In addition, cross-linking of the CD45 isoform by ANK12 induced tyrosine phosphorylation of specific proteins in NK cells. Subsequently, the involvement of CD45 in the negative signaling after "self" MHC class I recognition by rat NK cells was investigated. The anti-CD45 mAbs were found to affect NK cell-mediated lysis of syngeneic tumor cell lines, depending upon the expression level of MHC class I on target cells. mAbs ANK74 and OX1 only inhibited lysis of the syngeneic tumor cell lines that expressed low levels of MHC class I. Furthermore, both mAbs caused an inhibition of NK cell-mediated lysis of these tumor cell lines when MHC class I molecules on the tumor cell lines were masked by an Ab. These results suggest that CD45 regulates the inhibitory signal pathway after self MHC class I recognition, supposedly by dephosphorylation of proteins.     

Auto-tumor recognition following in vitro induction of MHC antigen expression on solid human tumors: stimulation of lymphocytes and generation of cytotoxicity against the original MHC-antigen-negative tumor cells

Summary Expression of major histocompatibility complex (MHC) class I antigens was induced in eight out of nine freshly prepared tumor cell suspensions by exposure to interferon (IFN) and tumor necrosis factor (TNF) in vitro. The untreated, class-I-antigen-negative, and the treated, antigen-positive, cells of three tumors (one breast carcinoma, one plasmocytoma and one ovarian carcinoma) were compared for the capacity to stimulate autologous and allogeneic blood lymphocytes, to generate auto-tumor cytotoxicity and for sensitivity to the lytic effect induced in autologous mixed lymphocyte tumor cell culture (MLTC). The MHC class I-negative cells did not stimulate, while the cells induced for expression of antigens did. On the other hand, when the autologous cytotoxic cells were generated in the MLTC by the class I antigen-positive tumor cells the class I-negative tumor cells were also damaged. Lysis of the class-I-positive tumor cells was abrogated by the W6/32 monoclonal antibody directed against the monomorphic part of the class I molecules.     

Detection of melanoma-reactive CD4+ HLA-class I-restricted cytotoxic T cell clones with long-term assay and pretreatment of targets with interferon-γ

Twenty-five CD4⁺ cytotoxic T lymphocyte (CTL) clones were obtained from the peripheral blood or tumor tissues of melanoma patients undergoing active specific immunotherapy. Melanoma-reactive T cells were cloned by limiting dilution using either autologous or allogeneic melanoma cells to stimulate their proliferation. Sixteen of the clones reacted against autologous melanoma cells but not against the autologous lymphoblastoid cell line, which we defined as melanoma-specific. Optimal demonstration of the lytic activity of CD4⁺ CTL required a 16-h incubation period and an effectortarget cell ratio of 401. In addition, a 24-h pre-incubation of the target melanoma cells with 100 U interferon (IFN) consistently augmented lysis by these CD4⁺ CTL, increasing it from a mean level of 20% to one of 52%. Lysis by 8 of the 11 melanoma-reactive CD4⁺ T cell clones was exclusively HLA-class-I-restricted, as judged by blocking with monoclonal antibodies (mAb). Five of these HLA class-I-restricted clones were reactive only with the autologous melanoma cells, while the other 3 clones were also reactive with allogeneic melanoma cells. In all cases, the T cells and melanoma targets shared at least one HLA class I allele, usually HLA-A2, HLA-C3 or HLA-B62. Interestingly, lysis by 2 of the 11 clones was inhibited by both anti-HLA-class-I or -HLA-class-II mAb, while lysis by 1 other clone was inhibited by neither. HLA class I molecules and several accessory molecules were maximally expressed by the melanoma target cells, both in terms of distribution and copy number before IFN treatment. Thus, IFN may have acted by increasing the expression of melanoma-associated epitopes as presented by HLA class I (or HLA class II) molecules. A proportion of human CD4⁺CTL appeared to recognize melanoma-associated epitopes presented by the HLA class I molecule, although their lytic potency may be less than that of their CD8⁺ counterparts.This work was supported by USPHS grant R01-CA 36233, and a grant from the Concern Foundation for Cancer Research.     

The mode of recognition of tumor antigens by noncytolytic-type antitumor T cells: Role of antigen-presenting cells and their surface class I and class II H-2 molecules

Summary The present study investigated the role of antigen-presenting cells (APC) in the activation of noncytolytic T cells against tumor antigens. The noncytolytic-type T cells exerted their antitumor effect by producing -interferon (IFN-) and by activating macrophages as the ultimate effectors. The production of IFN- by these noncytolytic T cells following the stimulation with tumor cells required the participation of Ia⁺ APC, since the depletion of APC from cultures of tumor-immunized spleen cells resulted in almost complete inhibition of the IFN- production. Both L3T4⁺ and Lyt-2⁺ subsets of T cells were capable of producing IFN-, and the requirement of APC for the production of IFN- was the case irrespective of whether noncytolytic T cells were of L3T4⁺ or Lyt-2⁺ phenotype. More importantly, it was demonstrated that the production of IFN- by L3T4⁺ and Lyt-2⁺ T cells was inhibited by addition of the respective anti-class II and anti-class I H-2 antibody to cultures. These results indicate that antitumor L3T4⁺ or Lyt-2⁺ noncytolytic T cells are activated for the IFN- production by recognizing tumor antigens in the context of self-class II or -class I H-2 molecules on APC.This work was supported by a Grant-in-Aid for the Special Project Cancer-Bioscience from the Ministry of Education, Science and Culture, Japan     

Impaired local natural killer cell activity in human colorectal carcinomas

Summary The present study was undertaken to study natural killer (NK) cell activity in patients with colorectal cancer at peripheral and local levels. Mononuclear cells were isolated from uninvolved colorectal mucosa, tumor tissue and peripheral blood, and tested against the colon carcinoma cell line CaCo-2 and the erythroleukemia cell line K-562. Peripheral blood NK cell activity from the patients showed similar levels compared with healthy controls, whereas, mononuclear cells of tumor tissue were found to have a significantly decreased NK cell activity compared to the normal intestinal mucosa (P<0.01). No relation was found between the NK cell activity and the advancement of the disease according to the Duke's stage. Interferon- (IFN-) stimulated the NK cell activity of the mononuclear cells from blood, mucosa and tumor. However, the increase of NK cell activity after IFN- stimulation was lower in the tumor compared to the mucosa (P<0.02). The lectin, phytohaemagglutinin, increased the cytotoxicity of mononuclear cells from blood, mucosa and tumor to a similar level. These results suggest that patients with colorectal tumors exhibit a normal NK cell activity in peripheral blood and intestinal mucosa; however, a diminished NK cell activity exists at the tumor level. Although mononuclear cells isolated from the tumor have a normal response to lectin stimulation they show hyporesponsiveness to IFN- stimulation with regard to their NK cell activity.     

Natural Killer Cell Tolerance Persists Despite Significant Reduction of Self MHC Class I on Normal Target Cells in Mice

Background

A major group of murine inhibitory receptors on Natural Killer (NK) cells belong to the Ly49 receptor family and recognize MHC class I molecules. Infected or transformed target cells frequently downmodulate MHC class I molecules and can thus avoid CD8⁺ T cell attack, but may at the same time develop NK cell sensitivity, due to failure to express inhibitory ligands for Ly49 receptors. The extent of MHC class I downregulation needed on normal cells to trigger NK cell effector functions is not known.

Methodology/Principal Findings

In this study, we show that cells expressing MHC class I to levels well below half of the host level are tolerated in an in vivo assay in mice. Hemizygous expression (expression from only one allele) of MHC class I was sufficient to induce Ly49 receptor downmodulation on NK cells to a similar degree as homozygous expression, despite a strongly reduced cell surface level of MHC class I. Co-expression of weaker MHC class I ligands in the host did not have any further effect on the degree of Ly49 downmodulation. Furthermore, a single MHC class I allele could downmodulate up to three Ly49 receptors on individual NK cells. Only when NK cells simultaneously expressed several Ly49 receptors and hemizygous MHC class I levels, a putative threshold for Ly49 downmodulation was reached.

Conclusion

Collectively, our findings suggest that in interactions between NK cells and normal untransformed cells, MHC class I molecules are in most cases expressed in excess compared to what is functionally needed to ensure self tolerance and to induce maximal Ly49 downmodulation. We speculate that the reason for this is to maintain a safety margin for otherwise normal, autologous cells over a range of MHC class I expression levels, in order to ensure robustness in NK cell tolerance.     

NXS2 murine neuroblastomas express increased levels of MHC class I antigens upon recurrence following NK-dependent immunotherapy

We evaluated recurrent NXS2 neuroblastoma tumors that developed following NK- or T-cell–mediated immunotherapy in tumor-bearing mice. Recurrent tumors developed following an NK-dependent antitumor response using a suboptimal dose of hu14.18-IL2, a humanized IL-2 immunocytokine targeted to the GD₂-ganglioside. This treatment initially induced complete resolution of measurable tumor in the majority of mice, followed, however, by delayed tumor recurrence in some mice. These recurrent NXS2 tumors revealed markedly enhanced (> fivefold) MHC class I antigen expression when compared with NXS2 tumors growing in PBS-treated control mice. A similar level of enhanced MHC class I antigen-expression could be induced on NXS2 cells in vitro by culturing with interferon , and was associated with reduced susceptibility to both NK-cell–mediated tumor cell lysis and antibody-dependent cellular cytotoxicity in vitro. In contrast, Flt3-ligand treatment of NXS2-bearing mice induced a protective T-cell–dependent antitumor memory response. Recurrent NXS2 tumors that developed following Flt3-L therapy revealed a decreased expression of MHC class I antigens. While NXS2 tumors are susceptible to in vivo destruction following either hu14.18-IL2 or Flt3-ligand immunotherapies, these results suggest that some tumor cells may be selected to survive and progress by expressing either higher or lower levels of MHC class I antigen in order to resist either NK- or T-cell–mediated antitumor responses, respectively.Abbreviations ADCC antibody-dependent cellular cytotoxicity - Flt3-L Flt3-ligand - GD₂ GD₂-disialoganglioside - IC immunocytokine - mAb monoclonal antibody - NB neuroblastoma - NXS2 transplantable murine neuroblastoma - s.c. subcutaneous     

Sequential changes in MHC antigen expression induced by the v-Ki-ras oncogene

A series of early-passage cell lines were transformed with the v-Ki-ras oncogene with the aim of examining the effect of an activatedras gene on the ability of these cells to express major histocompatibility complex (MHC) antigens. These cell lines were found to undergo multiple phenotypic changes upon transformation and subsequent proliferation. At early passage, the predominant effect ofras was an increased ability to express class II antigens when induced with interferon (IFN). For class I antigens, maximum levels of expression induced with IFN were largely unaffected, however, decreased sensitivity to induction with this lymphokine was noted. With subsequent in vitro or in vivo passage, both class I and class II antigen inducibility was attenuated. The latter phenotypic change was found to be transferable by coculture, implicating a soluble IFN antagonist. Conditioned media fromras-transformed cells treated to activate their latent transforming growth factor (TGF) content mediated similar changes in MHC antigen inducibility, suggesting that TGF\ may be involved in modulating MHC antigen expression inras-transformed cells.