Characterization of the major histocompatibility complex class I deficiencies in B16 melanoma cells.

The murine B16 melanoma system represents an important in vivo model for the evaluation of T cell-based immunization and vaccination strategies, although deficient MHC class I surface expression has been identified in these cells. We postulate here that the MHC class I-deficient phenotype of B16 melanoma cells is attributable to down-regulation or the loss of the expression and function of multiple components of the MHC class I antigen-processing pathway, including the peptide transporter associated with antigen processing, the proteasome subunits LMP2, LMP7, and LMP10, PA28alpha and -beta, and the chaperone tapasin. In contrast, calnexin, calreticulin, ER60, and protein disulfide isomerase expression are unaltered or only marginally suppressed in these cells. The level of down-regulation of the components of the antigen-processing pathway is either transcriptionally or posttranscriptionally controlled and could be corrected in all cases by IFN-y treatment, which also reconstituted MHC class I surface expression. Thus, B16 melanoma cells can be used as a model for the characterization of the mechanisms underlying the coordinated dysregulation of the antigen-processing components, which should provide new insights into the development of tumors and the factors controlling this process.

Coordinate downregulation of multiple MHC class I antigen processing genes in chemical-induced murine tumor cell lines of distinct origin.

In murine tumor cell lines, downregulation of MHC class I surface expression has been frequently detected, but the underlying molecular mechanisms of such deficiencies have not been defined. In this study, murine tumor cell lines of different histology derived from spontaneous or from chemical-induced tumors were analyzed for the expression of multiple components of the major histocompatibility complex (MHC) class I antigen-processing machinery (APM), including the peptide transporter TAP, the interferon (IFN)-gamma inducible proteasome subunits and several chaperones. The tumor cell lines analyzed demonstrated a heterogeneous expression pattern of various APM components. In comparison to control cells an impaired coordinated expression of at least three APM components was detected. In particular, extensive APM deficiencies were found in cell lines derived from chemical-induced tumors. A strong coordinated downregulation of expression and/or function of TAP, the low molecular weight proteins (LMP) subunits, the proteasome activator PA28 and/or tapasin was found in 5 of 10 tumor cells, which was associated with impaired MHC class I surface expression. In contrast, the expression of beta2-microglobulin (beta2-m), PA28beta, the constitutive proteasome subunits X, Y, Z and of the chaperones calnexin, calreticulin, ER60 and phospho disulfide isomerase (PDI) was unaltered or only weakly decreased. The deficient expression of APM components could be corrected by IFN-gamma treatment, which also reconstituted MHC class I surface expression. However, impaired expression of APM molecules appears not to be the only cause of abnormal MHC class I expression, since it could neither be corrected by the addition of exogeneous MHC class I binding peptides nor by incubation at low temperature. These results suggest that one major mechanism of murine tumor cells, in particular chemical-induced tumors, to evade the immune system is the combined dysregulation of various APM components and other factors, which still have to be identified.

Suppression of MHC class I antigens in oncogenic transformants: association with decreased recognition by cytotoxic T lymphocytes.

Cytotoxic T lymphocytes (CTLs) recognize peptide fragments derived from endogenous proteins, processed internally, and presented at the cell surface by major histocompatibility complex (MHC) class I molecules. The use of specific CTL for cancer therapy is limited because of their dependence on effective processing and presentation of appropriate antigenic peptides. Structural alterations, like point mutation or somatic loss, or dysregulation of key elements in the processing or presentation pathway, may allow cells to escape the immune surveillance. Indeed, the expression of MHC class I antigens on the surface of virus- and oncogene-transformed cells is low and correlates with tumorigenicity. Transformation of murine fibroblasts with the ras oncogene results in the suppression of cell surface expression of all H-2 loci as determined by FACScan analysis using a panel of monoclonal antibodies. We then examined whether the oncogene-mediated suppression of MHC class I surface expression was associated with reduced recognition of transformants by CD8+ T lymphocytes. Murine T lymphoma cells were stably transfected by the Ha-ras oncogene. The transfectants expressed distinct levels of the Ha-ras specific protein p21. Again, immunofluorescence analysis demonstrated an inverse correlation between oncogene and MHC class I surface expression in RMAras transformants. Allogeneic H-2Kb-restricted cytotoxic T lymphocytes were able to efficiently lyse the parental T lymphoma cells. In contrast, the CTL-mediated lysis of ras transformants was significantly downregulated compared with untransfected RMA cells. The efficiency of CTL-mediated lysis of RMAras cells was directly associated with reduced MHC class I membrane and high p21ras protein expression. Thus, the oncogene-mediated downregulation of MHC class I surface expression resulted in a reduced CTL response. Attempts are in progress to revert the defects in MHC class I surface expression of oncogenic transformants by introducing the different elements of the antigen presentation pathway. Such studies will not only provide improved understanding of the mechanisms of tumor escape, but also will suggest strategies to repair cellular defects in cancer patients having impaired expression of MHC class I antigens.

Multiple levels of MHC class I down-regulation by ras oncogenes.

A number of tumours and oncogene transformed cells displayed reduced MHC class I surface expression which seemed to enable their escape from immune surveillance. To test whether oncogenic activation is directly involved in suppressing MHC class I expression, a model of inducible oncogene expression was chosen. Mouse fibroblasts transfected with different oncogenes expressed under the control of the dexamethasone-inducible MMTV promoter were analysed in the presence and absence of hormone for the mRNA and protein expression of MHC class I molecules as well as the respective oncogenes. Immunofluorescence analyses demonstrated an inverse association of MHC class I and oncogene expression after dexamethasone stimulation, independent of the type of oncogene causing transformation. Hormone-mediated induction of oncogene expression caused down-regulation of all H-2 loci. Kinetic experiments using MMTV c-Ha-ras(A) transfectants revealed that down-regulation of MHC class I surface expression was preceded by a dexamethasone-induced change of morphology, anchorage-independent growth, and an increase of the ras protein p 21. Parallel monitoring of mRNA expression demonstrated a time-dependent up-regulation of ras specific transcripts, which was associated with differential regulation of MHC class I heavy and light chain transcripts. Beta2-microglobulin transcripts were transiently suppressed, whereas MHC class I heavy chain transcripts remained unaffected. To investigate the mechanisms of oncogene-mediated down-regulation of MHC class I expression, H-2 promoter transfections and a nuclear run on assays were performed. In MMTV c-Ha-ras(A) cells, neither alterations of the H-2 promoter activity nor of the transcriptional activity of H-2 antigens was observed in the presence of dexamethasone, whereas both could be up-regulated by interferon-gamma treatment. These data suggest that oncogene-mediated transformation is directly associated with MHC class I down-regulation, but that complex interactions affecting MHC class I heavy and light chain genes at the transcriptional and/or post-transcriptional level are involved in this process.