A synthetic peptide homologous to functional domain of human IL-10 down-regulates expression of MHC class I and Transporter associated with Antigen Processing 1/2 in human melanoma cells

Tumor cells treated with IL-10 were shown to have decreased, but peptide-inducible expression of MHC class I, decreased sensitivity to MHC class I-restricted CTL, and increased NK sensitivity. These findings could be explained, at least partially, by a down-regulation of TAP1/TAP2 expression. In this study, IT9302, a nanomeric peptide (AYMTMKIRN), homologous to the C-terminal of the human IL-10 sequence, was demonstrated to mimic these previously described IL-10 effects on MHC class I-related molecules and functions. We observed a dose-dependent down-regulation of MHC class I at the cell surface of melanoma cells after 24-h treatment with IT9302. The IL-10 homologue peptide also caused a dose-dependent inhibition of the IFN-gamma-mediated surface induction of MHC class I in a melanoma cell line. We demonstrated, using Western blot and flow cytometry, that IT9302 inhibits the expression of TAP1 and TAP2 proteins, but not MHC class I H chain or low molecular protein molecules. Finally, peptide-treated melanoma cells were shown to be more sensitive to lysis by NK cells in a dose-dependent way. Taken together, these results demonstrate that a small synthetic peptide derived from IL-10 can mimic the Ag presentation-related effects mediated by this cytokine in human melanomas and increase tumor sensitivity to NK cells, which can be relevant in the designing of future strategies for cancer immune therapy.     

Stimulation of murine natural killer (NK) cells by a monoclonal antibody specific for the NK1.1 antigen. IL-2-activated NK cells possess additional specific stimulation pathways

NK cells lyse certain tumor cell targets but the effector cell surface molecules responsible for this reactivity remain uncertain. The allotypic NK1.1 Ag is the most specific serologic marker on murine cells that display non-MHC-restricted cytolysis of tumor cell targets, but no function has been previously ascribed to this Ag. In this report, we demonstrate that, in the presence of a mAb specific for the NK1.1 Ag (mAb PK136), freshly isolated and IL-2-activated NK cells from C57BL/6 mice can be induced to lyse an otherwise resistant target cell, Daudi. This phenomenon is effector and mAb specific because NK cells derived from BALB/c mice do not express the NK1.1 Ag and cannot be triggered by mAb PK136. We demonstrate that IL-2 activated but not freshly isolated NK cells express the Ly-6 and VEA Ag, originally described as T cell activation Ag. Moreover, mAb specific for Ly-6 and VEA induce target cell lysis by IL-2 activated but not freshly isolated NK cells. These mAb effects are specific, concentration dependent, and display kinetics that are similar to spontaneous cytolysis of NK-sensitive targets. The Fc portion of the activating antibodies and only FcR bearing target cells participate in mAb-induced activation, consistent with the mechanism of redirected lysis. Finally, analysis of Daudi cells transfected with beta 2-microglobulin gene demonstrate that the expression of MHC class I Ag by the target cell does not affect its sensitivity to mAb-induced lysis by NK cells. These data demonstrate that the NK1.1 Ag is functionally active on both freshly isolated and IL-2-activated NK cells and that IL-2-activated NK cells possess additional pathways of specific stimulation.     

H-2 antigen expression and sensitivity of BL6 melanoma cells to natural killer cell cytotoxicity

The sensitivity of H-2b-high and H-2b-low variants of BL6 melanoma to the cytotoxic action of NK and lymphokine-activated killer cells was investigated. BL6 mouse melanoma cells lack detectable H-2Kb and had low levels of expression of H-2Db Ag. The BL6T2 variant cells, obtained after treatment of BL6 cells with mutagen N-methyl-N-nitro-N'-nitro-soguanidine, had relatively high levels of expression of class I H-2b Ag. Poly(I:C)-stimulated spleen cells of nude mice were highly cytotoxic for BL6T2, whereas H-2b-low BL6 cells were less sensitive to NK activity in an 18-h 51Cr-release assay. Similar results were obtained after 4-h incubation of radio-labeled tumor cells with IL-2-activated effector cells. In contrast, both lines were equally sensitive to lysis by purified granules derived from rat large granular lymphocytes (LGL) or by macrophages. By using various clones selected from BL6 or BL6T2 cells, it was found that BL6 or BL6T2 clones with low H-2b Ag expression were less sensitive to lysis by NK cells than H-2b-high clones. After IFN treatment of either BL6 or BL6T2, the target cells became more resistant to lysis by either NK cells or by purified LGL granules. IFN-treated BL6 cells had substantially increased expression of H-2b Ag and in this respect became similar to untreated BL6T2. However, IFN-treated BL6 cells were more resistant than BL6T2 cells to lysis by NK cells and LGL granules, suggesting that augmentation of H-2b Ag expression and NK resistance could be two independent IFN-induced effects. With a cold target inhibition assay, it was found that BL6T2 or its H-2 positive clones were highly competitive and inhibited the cytotoxic activity of NK and lymphokine-activated killer cells against radiolabeled YAC-1 and BL6T2, whereas BL6 cells or H-2-negative clones of BL6T2 and BL6 lines showed poor competitive ability. Thus, our data indicate that the NK resistance of H-2-low BL6 cells may be due to a paucity of NK recognizable determinants. N-Methyl-N-nitro-N'-nitroguanidine treatment of BL6 melanoma cells was associated with an increase in class I H-2b Ag expression and NK sensitivity, suggesting the involvement of class I MHC Ag in the sensitivity of tumor cells to NK cell-mediated cytotoxicity.     

IFN-gamma production and cytotoxicity of IL-2-activated murine NK cells are differentially regulated by MHC class I molecules

Activation of NK cells by target cells leads to cytotoxicity as well as production of various cytokines including IFN-gamma. MHC class I molecules on target cells regulate NK cytotoxicity. However, little is known about the regulation of IFN-gamma production by NK cells. We examined the production of IFN-gamma in individual murine NK cells stimulated with tumor cell lines by flow cytometric analysis of intracellular IFN-gamma. Among several tumor lines tested, the rat basophilic leukemia line RBL-1 induced particularly high level of IFN-gamma production in IL-2-activated NK cells, whereas other lines, including the prototypic NK target YAC-1, induced very low or no IFN-gamma production. Transfection of murine classical MHC class I molecules into RBL-1 cells substantially inhibited IFN-gamma production. This inhibition of IFN-gamma production by MHC class I was independent of Ly-49 or CD94/NKG2A expression on NK cells. These results indicate that some target cells directly stimulate IL-2-activated NK cells and induce IFN-gamma production, but the requirements for the induction of IFN-gamma production seem different from those for NK cytotoxicity. Furthermore, similar to NK cytotoxicity, induction of IFN-gamma production is inhibited by MHC class I on stimulating cells. However, the MHC class I-specific receptors inhibiting IFN-gamma production are different from those for NK cytotoxicity.     

Stress renders T cell blasts sensitive to killing by activated syngeneic NK cells

Exposure of primary T cell blasts to stress in the forms of heat, hydrogen peroxide, or high-density growth conditions resulted in a state of enhanced susceptibility to killing by syngeneic IL-2-activated NK cells or lymphokine-activated killer cells, but not to killing by CTL. Cytotoxicity was perforin mediated and was not due to decreased target expression of total MHC class I. The levels of stress used had little effect on cell viability. For thermal stress, sensitization increased with temperature, required a minimum exposure time, and disappeared when cells were given a long enough recovery time. Our data support a model that predicts that activated NK cells play a role in the immunosurveillance of nontransformed stressed cells in normal animals.     

Adoptive immunotherapy of syngeneic murine leukemia is enhanced by the combination of recombinant IFN-gamma and a tumor-specific cytotoxic T cell clone

Mice with an established syngeneic T cell tumor (RBL5) received short term adoptive chemoimmunotherapy with CTL clone 1.B6 and murine rIFN-gamma. In comparison with treatment with either agent alone, the combination of 1.B6 and rIFN-gamma was associated with a dramatic increase in long term survival. No direct effects of rIFN-gamma on tumor cell proliferation, MHC Ag expression, or susceptibility to CTL-mediated lysis could be demonstrated to explain the prolongation of survival. However, rIFN-gamma induced a distinct increase in broad-spectrum cytolytic capacity of peritoneal exudate cells and further increased class II MHC expression on peritoneal macrophages. The explanation for enhanced adoptive chemoimmunotherapy after combined short term administration of a CTL clone and rIFN-gamma is uncertain. Potential mechanisms include direct tumor lysis by activated cells, indirect tumor lysis via sensitization to other lymphokines or monokines, improved Ag-specific activation of transferred CTL clones, and/or more effective development of de novo host anti-tumor immunity.     

Properties and characterization of a rat spleen cell-derived factor that induces resistance to natural killer cell lysis in YAC lymphoma cells

Supernatants of Con A-stimulated rat spleen cell cultures contain a factor that induces relative resistance to NK cell-mediated cytotoxicity in the YAC cell line, a line that is otherwise highly susceptible to murine NK cell-mediated lysis. This NK-lysis resistance-inducing factor (LRIF) has a Mr of 12,600 Da, as determined by gel filtration chromatography, and an isoelectric pH of 4.8. NK-LRIF is heat labile and is de-activated by treatment with proteolytic enzymes. Unlike immune-IFN (IFN-gamma), NK-LRIF is not inactivated by pH 2 treatment, and antibodies capable of neutralizing IFN-alpha and IFN-gamma do not abrogate the effect of NK-LRIF. Highly purified IL-2 preparations lack NK-LRIF activity. NK-LRIF does not induce a general resistance to lysis in YAC cells, because control and NK-LRIF-treated YAC cells were equally susceptible to alloimmune cytotoxic T cells. YAC cells treated with NK-LRIF showed a marked enhancement (5- to 10-fold) in the expression of class I MHC Ag. This observation supports the proposition that the NK susceptibility of target cells could be inversely related to the expression of class I MHC Ag.     

Mouse Hepa-1 tumor is rejected by H-2Db-restricted CTL despite decreased MHC class I antigen expression

It has recently been hypothesized that tumor cells with reduced levels of MHC class I antigens are more susceptible to NK-mediated lysis and are rejected by NK cells, whereas tumor cells with normal levels of class I are rejected by tumor-specific CTL. We have tested this hypothesis using a mouse hepatoma system. The Hepa-1 tumor is a spontaneous H-2Kb loss variant that arose from the BW7756 tumor, when BW7756 was adapted to growth in culture. Our studies have shown that despite the loss of H-2Kb antigen, Hepa-1 is not more susceptible to NK lysis than its H-2Kb-transfected variants. These studies also suggested that NK cells were not responsible for rejection of the Hepa-1 tumor. The Hepa-1 tumor, therefore, appears to contradict the hypothesized linkage of MHC levels and NK susceptibility. Because NK cells are not involved in immunity to this tumor, we have sought to identify the effector cell responsible for Hepa-1 rejection. Cytotoxic T lymphocyte assays demonstrate that in vitro, Hepa-1 cells are lysed by Hepa-1-specific H-2Db-restricted CD4-CD8+ T lymphocytes. Footpad assays demonstrate that in vivo, Hepa-1 rejection requires CD4+CD8- and CD4-CD8+ Hepa-1-primed splenocytes. These results indicate that immunity to Hepa-1 is T cell mediated. Hepa-1 is therefore an example of an unusual tumor in that down-regulation of MHC class I antigen expression is associated with increased CTL susceptibility.     

Rejection of allogeneic tumor is not determined by host responses to MHC class I molecules and is mediated by CD4-CD8+ T lymphocytes that are not lytic for the tumor

In previous studies, the murine SaI (A/J derived, KkDd) sarcoma was transfected with the allogeneic MHC class I H-2Kb gene, and expressed high levels of H-2Kb antigen. Contrary to expectations, the tumor cells expressing the alloantigen (SKB3.1M tumor cells) were not rejected by autologous A/J mice. Because these results contradict the laws of transplantation immunology, the present studies were undertaken to examine the immunogenicity of SKB3.1M and SaI cells in allogeneic hosts. Similar to SKB3.1M, SaI cells are lethal in some allogeneic strains, despite tumor-host MHC class I incompatibilities. Tumor challenges of SKB3.1M and SaI cells, however induce MHC class I-specific antibodies and CTL in both tumor-resistant and -susceptible hosts. Although the tumors induce specific CTL, tumor cells are not lysed in vitro by these CTL, suggesting that the tumor cells are resistant to CTL-mediated lysis. Since growth of these tumors does not follow the classical rules of allograft transplantation, and because the tumor is not susceptible to CTL-mediated lysis, we have used Winn assays to identify the effector lymphocyte(s) responsible for SaI rejection. Depletion studies demonstrate that the effector cell is a CD4-CD8+ T lymphocyte. Collectively these studies suggest that the host's response to MHC class I alloantigens of SKB3.1M and SaI cells does not determine tumor rejection, and that effector cells other than classically defined CTL, but with the CD4-CD8+ phenotype, can mediate tumor-specific immunity.     

Inhibitory effect of herpes simplex virus infection to target cells on recognition of minor histocompatibility antigens by cytotoxic T lymphocytes

Target cell lysis by CTL specific for minor histocompatibility Ag (minor HA), which were generated in (C3H/He x BALB/c)F1 mice immunized with A/J mouse spleen cells, was dramatically reduced by infection of HSV to Neuro-2a (A/J mouse origin) cells as target. The reduction was apparent at 5 h after infection of HSV to target cells, when many viral proteins were produced in the cells. Conversely, MHC-restricted HSV-specific CTL-mediated cell lysis increased time dependently. Using an RNA virus, vesicular stomatitis virus, significant reduction of minor specific CTL-mediated target cell lysis was also found. During the time when this reduction of target cell lysis by HSV occurred, the surface expression of class I H-2Dd molecules was maintained, and anti-H-2a allo-MHC-specific CTL lysed HSV-infected Neuro-2a cells as strongly as uninfected Neuro-2a cells. When HSV-infected or uninfected Neuro-2a cells were treated with Brefeldin A that selectively blocks transportation of newly synthesized proteins out of endoplasmic reticulum, both HSV- and minor HA-specific CTL-mediated cell lyses were blocked. These observations demonstrated that minor HA are continuously synthesized and associated with class I molecules at pre-Golgi and transported via trans Golgi system with quick turnover, and that newly synthesized HSV Ag, which are also associated with class I molecules and transported via the same system, should take the place of intrinsic minor HA and be presented on the surface of the cells to be recognized by MHC-restricted CTL.     

Alteration of the metastatic potential of line 1 lung carcinoma cells: opposite effects of class I antigen induction by interferons versus DMSO or gene transfection.

Class I antigens are necessary for the recognition of tumor cells by cytotoxic T lymphocytes (CTL). The line 1 lung carcinoma is a spontaneous murine tumor deficient in class I antigen expression. Consistent with this, line 1 cells are highly metastatic in vivo. We investigated whether increasing class I antigen expression on line 1 cells could alter the metastatic potential of these tumor cells using an in vivo lung metastasis model. We used three methods to induce class I antigen expression on line 1 cells: gene transfection, treatment with dimethyl sulfoxide (DMSO), or treatment with interferon (IFN)-beta or -gamma. We found that line 1 cells expressing a transfected class I gene were significantly less metastatic than parental line 1 cells. DMSO-treated line 1 cells also formed significantly fewer metastases than parental line 1 cells. These results indicate that increased class I antigen expression decreases the metastatic potential of line 1 cells in vivo. However, we did not observe a significant decrease in the number of lung metastases in mice receiving line 1 cells treated with IFN-beta or -gamma, despite high levels of class I antigen expression. Thus, increasing class I antigen expression with IFN has an opposite effect on metastasis from class I antigen expression induced by transfection or DMSO. These results show that the method used to increase class I antigen expression is critical in terms of the in vivo effect observed. To investigate a possible mechanism for the differences observed in vivo between these class I expressing cells, we tested whether IFN alters or blocks susceptibility of line 1 cells to immune effector cells. We found IFN treatment increased the ability of line 1 cells to be recognized by CTL but concomitantly decreased the susceptibility of line 1 cells to NK cell lysis by a non-class I antigen-related mechanism. In contrast, transfected or DMSO-treated line 1 cells which were less metastatic in vivo were susceptible to both CTL and NK-mediated lysis. Taken together, these results suggest that immune intervention against metastasizing line 1 cells may involve NK cells and CTL.     

CD66a interactions between human melanoma and NK cells: a novel class I MHC-independent inhibitory mechanism of cytotoxicity

NK cells are able to kill virus-infected and tumor cells via a panel of lysis receptors. Cells expressing class I MHC proteins are protected from lysis primarily due to the interactions of several families of NK receptors with both classical and nonclassical class I MHC proteins. In this study we show that a class I MHC-deficient melanoma cell line (1106mel) is stained with several Ig-fused lysis receptors, suggesting the expression of the appropriate lysis ligands. Surprisingly, however, this melanoma line was not killed by CD16-negative NK clones. The lack of killing is shown to be the result of homotypic CD66a interactions between the melanoma line and the NK cells. Furthermore, 721.221 cells expressing the CD66a protein were protected from lysis by YTS cells and by NK cells expressing the CD66a protein. Redirected lysis experiments demonstrated that the strength of the inhibitory effect is correlated with the levels of CD66a expression. Finally, the expression of CD66a protein was observed on NK cells derived from patients with malignant melanoma. These findings suggest the existence of a novel class I MHC-independent inhibitory mechanism of human NK cell cytotoxicity. This may be a mechanism that is used by some of the class I MHC-negative melanoma cells to evade attack by CD66a-positive NK cells.     

Tissue distribution of human minor histocompatibility antigens. Ubiquitous versus restricted tissue distribution indicates heterogeneity among human cytotoxic T lymphocyte-defined non-MHC antigens.

We determined the tissue distribution of 7 human minor histocompatibility (H) Ag. Each of these Ag is defined by one or more MHC class I-restricted CTL clones, previously generated from PBL primed against minor H Ag by HLA-identical bone marrow transplantation (BMT). CTL-mediated lysis of tissue-derived cells and cultured cell lines was used as an in vitro assay for minor H Ag expression of several human tissues. The Ag HA-3 (HLA-A1-restricted), HA-4 (HLA-A2 restricted), HA-6 and HA-7 (HLA-B7 restricted), and the male-specific Ag H-Y (HLA-A2 and B7 restricted) were found to be expressed on cells of all tissues tested. In contrast, the HLA-A2-restricted Ag HA-1 and HA-2 were demonstrated on PHA-blasts, EBV-BLCL, purified T cells, B cells, monocytes, and immature thymocytes, but could not be demonstrated on skin-derived cultured fibroblasts, keratinocytes, melanocytes, cultured epithelial cells of kidney proximal tubili, and umbilical cord vein-derived endothelial cells. Incubation of the latter cell lines with rIFN-gamma, rTNF-alpha, and/or rIL-1 alpha, in concentrations shown to maximally increase their susceptibility to lysis by allo-MHC class I CTL, did not induce recognition by HA-1- and HA-2-specific CTL in vitro. These results indicate an ubiquitous tissue expression of the minor H Ag HA-3, -4, -6, -7 and H-Y in contrast to a to the hemopoietic cell lineage-restricted expression for HA-1 and HA-2. The heterogeneity in tissue expression of T cell-defined, class I-restricted non-MHC Ag implies that they might be derived from intracellular proteins with either an ubiquitous or a more specialized cell type-specific function.     

Trophoblast cell line resistance to NK lysis mainly involves an HLA class I-independent mechanism

The lack of classical HLA molecules on trophoblast prevents allorecognition by maternal T lymphocytes, but poses the problem of susceptibility to NK lysis. Expression of the nonclassical class I molecule, HLA-G, on cytotrophoblast may provide the protective effect. However, the class I-negative syncytiotrophoblast escapes NK lysis by maternal PBL. In addition, while HLA-G-expressing transfectants of LCL.721.221 cells are protected from lymphokine-activated killer lysis, extravillous cytotrophoblast cells and HLA-G-expressing choriocarcinoma cells (CC) are not. The aim of this work was therefore to clarify the role of HLA class I expression on trophoblast cell resistance to NK lysis and on their susceptibility to lymphokine-activated killer lysis. Our results showed that both JAR (HLA class I-negative) and JEG-3 (HLA-G- and HLA-Cw4-positive) cells were resistant to NK lysis by PBL and were equally lysed by IL-2-stimulated PBL isolated from a given donor. In agreement, down-regulating HLA class I expression on JEG-3 cells by acid treatment, masking these molecules or the putative HLA-G (or HLA-E) receptor CD94/NKG2 and the CD158a/p58.1 NKR with mAbs, and inducing self class I molecule expression on JAR cells did not affect NK or LAK lysis of CC. These results demonstrate that the resistance of CC to NK lysis mainly involves an HLA class I-independent mechanism(s). In addition, we show that the expression of a classical class I target molecule (HLA-B7) on JAR cells is insufficient to induce lysis by allospecific polyclonal CTL.     

Activated,but not resting,T cells can be recognized and killed by syngeneic NK cells

We demonstrate that IL-2-activated NK cells or lymphokine-activated killer cells recognize and kill syngeneic CD4(+) and CD8(+) T cells that have been activated by APCs. Induction with APC required TCR-specific Ag, and lysis was perforin mediated. Brefeldin A, which disrupts protein transport, inhibited the sensitivity induced by activation. In BALB/c, expression of NKG2D ligands correlated with lysis and could be inhibited by brefeldin A. As well, addition of anti-NKG2D mAb to a killing assay completely abrogated lysis. Transduction of mouse NKG2D into a human NK cell line, YTSeco, conferred upon it the ability to kill activated BALB/c T cells, indicating that NKG2D is necessary for recognition. Our data provide a basis for studying a role for NK cells in T cell regulation.     

Interferon-gamma upregulates the susceptibility of human neuroblastoma cells to interleukin-2-activated natural killer cells

The influence of interferon-gamma on the susceptibility of neuroblastoma cells in cell-mediated killing was investigated. Neuroblastoma cells were only weakly susceptible targets for peripheral mononuclear cells. However, enrichment of natural killer (NK) cells or activation of NK cells with interleukin-2 resulted in a considerable increase of neuroblastoma cell lysis. Pretreatment of neuroblastoma targets with interferon-gamma additionally increased the susceptibility to enriched NK cells as well as to interleukin-2-activated NK cells. The conjugate formation between enriched NK cells and the neuroblastoma targets was not affected by the pretreatment of the targets with interferon-gamma. Concomitantly, treatment of the neuroblastoma targets with interferon-gamma resulted in a strong induction of otherwise poorly expressed major histocompatibility complex (MHC) class I antigen expression. These results suggest that the increased expression of MHC class I antigens on target cells is not always correlated with decreased sensitivity for NK cells but can also be followed by an increased susceptibility for NK cells.     

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.     

Mutational analysis of regulation of MHC and anti-viral genes.

CTL-mediated selection for loss of expression of Mta by H-2-heterozygous SV40-transformed mouse fibroblasts (line 24SV) produced an unusual phenotypic class of maternally transmitted Ag negative mutants defective in both MHC expression and in anti-viral activity. Severely reduced surface expression of class I MHC Ag from multiple loci of both haplotypes correlated with low levels of MHC H chain and beta 2-microglobulin mRNA. Inasmuch as IFN can up-regulate class I expression and some fibroblasts elaborate autocrine IFN-beta, we examined whether IFN could restore wild-type expression of class I MHC Ag. However, IFN could not restore wild-type expression. Moreover, the fold-increases in class I Ag and mRNA expression were significantly reduced in mutant cells compared to wild-type cells. These results suggested that the mutants might have generalized defects in IFN response. Inasmuch as the induction of an anti-viral state is a hallmark of IFN responses, we exposed cells to IFN-alpha, -beta, or -gamma and challenged with virus. 24SV cells, exposed to any of the three IFNs, were completely protected from destruction by vesicular stomatitis, mengovirus or respiratory syncytial viruses. In contrast, MHC and anti-viral defective mutants could not be protected from virus-induced lysis by any IFN. Somatic cell hybridization analyses indicated that both basal MHC and IFN-inducible phenotypes were recessive to wild-type, and that a trans-acting regulatory factor required for basal MHC expression is defectively expressed in the mutants. Such a factor may integrate the organismal response to virus infection, encompassing both immune and nonimmune anti-viral responses.     

Increase in the ability of human cancer cells to induce cytotoxic T lymphocytes by ultraviolet irradiation

The roles of ultraviolet-B (UV) radiation in the immunogenicity of human cancer cells have not been fully studied. We have investigated the effects of UV radiation on metastatic melanoma and renal cell carcinoma cells with regard to MHC antigen expression and the ability to induce cytotoxic T lymphocyte (CTL) activity in peripheral blood mononuclear cells (PBMC) or tumor-infiltrating lymphocytes (TIL) against untreated autologous tumor cells. UV radiation respectively decreased or increased MHC class I expression of freshly isolated tumor cells or cultured tumor cells, and also decreased MHC class I expression of starved cultured tumor cells. It increased the ability of both freshly isolated and cultured tumor cells to induce CTL activity from PBMC against untreated autologous tumor cells. UV-irradiated subclones that were more susceptible to CTL lysis were more potent for CTL induction from TIL than either an untreated parental clone or a UV-irradiated subclone that was resistant to CTL lysis. In summary, UV radiation increased the ability of tumor cells to induce CTL activity without a corresponding effect on MHC antigen expression.This work was supported in part by a grant CA47891 from the National Cancer Institute, USA, a grant-in-aid of the comprehensive 10-years strategy for cancer control from ministry of a Health and Welfare, Japan, and the Ishibashi Research Fund, Japan     

Unrestricted recognition of a nonpeptide antigen by CD8+ cytolytic T lymphocytes

CD8+ murine CTL that are specific for an unusual nonpeptide Ag, the heme moiety of hemoglobin, have been derived by in vitro stimulation of spleen cells with hemin. Such CTL demonstrate a requirement for the expression of class I Ag on target cells, yet appear to be unrestricted to the extent that both syngeneic and allogeneic targets precoated with hemin are sensitive to lysis. A series of CTL clones with specificity for hemin was derived from C57BL/6 mice. They exhibited the same type of promiscuous recognition that was observed in CTL populations from a number of different strains. The possibility that hemin acts as a nonspecific mediator of lysis by CTL was ruled out by the fact that a variety of CTL populations and clones specific for different Ag did not exhibit hemin-specific lysis. Some explanations offered to explain these results include 1) the possibility that hemin is recognized by binding to a site on the MHC other than the Ag-binding groove, and 2) the possibility that TCR recognition of a rigid molecule, such as hemin, may be less sensitive to polymorphic variation in the MHC than is recognition of a conventional peptide Ag whose conformation may differ significantly when bound to MHC molecules whose sequences differ within the Ag-binding groove.