Barbara Seliger

Antigen-processing machinery breakdown and tumor growth

Defects in the major histocompatibility complex (MHC) class I antigen-processing machinery (APM) have been described in tumors of different histology. Murine data suggest that defects in the MHC class II APM might also be associated with malignant transformation of human cells. This article describes the pathophysiology of the MHC class I and II APM, reviews APM abnormalities in tumor cells and discusses their role in the escape of tumor cells from in vitro recognition by T cells.

TAP off — tumors on

Abstract The molecular characterization of T-cell-defined tumor-associated antigens has provided targets for cell-mediated immunotherapy for malignant diseases. The success of this strategy is negatively influenced by structural and functional abnormalities of major histocompatibility complex (MHC) class I molecules, which provide tumor cells with resistance to T-cell-mediated immune recognition. This article reviews the physiology of the MHC class I processing machinery and describes the deficiencies of this pathway in malignant cells.

Tumor-specific T cell activation by recombinant immunoreceptors : CD3 zeta signaling and CD28 costimulation are simultaneously required for efficient IL-2 secretion and can be integrated into one combined CD28/CD3 zeta signaling receptor molecule

Recombinant immunoreceptors with specificity for the carcinoembryonic Ag (CEA) can redirect grafted T cells to a MHC/Ag-independent antitumor response. To analyze receptor-mediated cellular activation in the context of CD28 costimulation, we generated: 1) CEA+ colorectal tumor cells that express simultaneously B7-1 and B7-2, and 2) CEA-specific immunoreceptors that harbor intracellularly the signaling moities either of CD28 (BW431/26-scFv-Fc-CD28), CD3ζ (BW431/26-scFv-Fc-CD3ζ), or FcεRIγ (BW431/26-scFv-Fc-γ). By retroviral gene transfer, we grafted activated T cells from the peripheral blood with these immunoreceptors. T cells that express the FcεRIγ or CD3ζ signaling receptor lysed specifically CEA+ tumor cells and secreted high amounts of IFN-γ upon receptor cross-linking, whereas anti-CEA-CD28 receptor-grafted T cells did not, indicating that CD28 signaling alone is not sufficient for efficient T cell activation. CD28 costimulation did not affect cytolysis by T cells equipped with γ- or ζ-signaling receptors, but enhanced both IFN-γ secretion and proliferation. CD28 costimulation, however, was required for efficient IL-2 secretion of anti-CEA-γ receptor-grafted T cells. Both purified CD4+ and CD8+ T cells grafted with immunoreceptors required CD28 costimulation for complete T cell activation. We integrated both CD28 and CD3ζ signaling domains into one combined immunoreceptor molecule (BW431/26-scFv-Fc-CD28/CD3ζ) with dual signaling properties. T cells grafted with the combined CD28/CD3ζ signaling receptor secreted high amounts of IL-2 upon Ag binding without exogenous B7/CD28 costimulation, demonstrating that both MHC-independent cellular activation and CD28 costimulation for complete T cell activation can be delivered by one recombinant receptor molecule.

Small interfering RNA (siRNA) inhibits the expression of the Her2/neu gene, upregulates HLA class I and induces apoptosis of Her2/neu positive tumor cell lines.

Silencing of a specific mRNA using double stranded RNA oligonucleotides represents one of the newest technologies for suppressing a specific gene product. Small interfering RNA (siRNA) are 21 nucleotides long, double stranded RNA fragments that are identical in sequence to the target mRNA. We designed 3 such siRNA against the Her2/neu (HER2) gene. The HER2 gene is known to play an important role in the oncogenesis of several types of cancers, such as breast, ovarian, colon and gastric cancers. Introduction of the siRNA into HER2 positive tumor lines in vitro greatly reduced the cell surface expression of the HER2 protein. Concurrently, a range of effects on cell physiology, such as growth inhibition or apoptosis, was observed. The expression of HLA class I was observed to be upregulated when HER2 was silenced with siRNA. Treatment of SKBr3 and MCF7/HER2 tumor cell lines with the HER2 siRNA resulted in growth arrest of cells in the late G1/S‐phase. Our results suggest that siRNA may be an effective method of abrogating the effect of HER2 in tumorigenesis.

Upregulation of Major Histocompatibility Complex Class I on Liver Cells by Hepatitis C Virus Core Protein via p53 and TAP1 Impairs Natural Killer Cell Cytotoxicity

ABSTRACT The mechanisms of immune evasion and the role of the early immune response in chronic infection caused by hepatitis C virus (HCV) are still unclear. Here, we present evidence for a cascade of molecular events that the virus initiates to subvert the innate immune attack. The HCV core protein induced p53-dependent gene expression of TAP1 (transporter associated with antigen processing 1) and consecutive major histocompatibility complex (MHC) class I upregulation. Moreover, in p53-deficient liver cell lines, only reconstitution with wild-type p53, but not mutated p53 lacking DNA binding capacity, showed this effect. As a consequence of increased MHC class I expression, a significantly downregulated cytotoxic activity of natural killer (NK) cells against HCV core-transfected liver cells was observed, whereas lysis by HCV-specific cytotoxic T cells was not affected. These results demonstrate a way in which HCV avoids recognition by NK cells that may contribute to the establishment of a chronic infection.

HLA-G and MIC expression in tumors and their role in anti-tumor immunity

Non-classical MHC class Ib molecules have attracted growing interest in recent years, especially because they interact with non-T-cell inhibitory or triggering receptors expressed on natural killer (NK) and T cells, suggesting that they have a role in immune recognition. Abnormalities in MHC class Ib expression are frequently found in human tumors of various histologies and might be associated with poor clinical outcome despite the local accumulation of immune competent cells. Available data suggest that the balance between activating and suppressing signals significantly influences the efficacy of the immune response and consequently of tumor progression.

MHC class I antigen processing pathway defects, ras mutations and disease stage in colorectal carcinoma

Colorectal tumorigenesis has been associated with the progressive acquisition of a variety of genetic alterations. These include mutations of the Ki‐ras proto‐oncogene in codons 12 and 13, which account for 85% of genetic changes in colorectal cancer. In murine in vitro models of oncogenic transformation, an association between ras‐mediated transformation and downregulation of different components of the MHC class I antigen processing machinery (APM) has been described. In order to investigate whether this association also exists in human tumors, 10 cases of high‐grade intraepithelial neoplasia (HIN), as well as primary tumors and autologous lymph node metastases from 42 patients with colorectal carcinoma, were monitored by allele‐specific restriction analysis for Ki‐ras mutations. In parallel, APM component expression and tumor cell proliferation were analyzed by immunohistochemistry. In comparison to autologous colorectal mucosa, TAP1, LMP2 and tapasin loss was found in 68%, 67% and 80% of HIN, respectively. In contrast, impaired TAP1, LMP2 and tapasin expression was found in 42%, 42% and 63% of primary adenocarcinomas of stage III disease and in 63%, 47% and 79% of the matched lymph node metastases, respectively. More than 60% of colorectal tumor lesions with TAP1, LMP2 and/or tapasin defects displayed Ki‐ras mutations. The frequency of TAP1, LMP2 and tapasin loss varied between 33% of primary adenocarcinomas, 40% of HIN to approximately 67% of metastases. These data suggest that i) APM component deficiencies occur more frequently in Ki‐ras‐mutated colorectal carcinoma lesions and ii) APM abnormalities in conjunction with Ki‐ras mutations appear to be associated with disease stage. These findings support the hypothesis that Ki‐ras mutations may contribute to immune escape mechanisms of tumors by downregulating the MHC class I APM component expression.

Identification of metabolic enzymes in renal cell carcinoma utilizing PROTEOMEX analyses.

PROTEOMEX, an approach which combines conventional proteome analysis with serological screening, is a powerful tool to separate proteins and identify immunogenic components in malignant diseases. By applying this approach, we characterized nine metabolic enzymes which were differentially expressed in renal cell carcinoma (RCC) cell lines and compared their expression profiles to that of normal kidney epithelium cells. Four of these proteins, superoxide dismutase (SODC), triosephosphatase isomerase (TPIS), thioredoxin (THIO) and ubiquitin carboxyl-terminal hydrolase (UBL1) were further analysed for both their constitutive and interferon (IFN)-gamma inducible protein expression pattern in cell lines or tissue specimens derived from RCC or normal kidney epithelium using Western blot analysis and immunohistochemistry, respectively. With the exception of the RCC cell line MZ1940RC, which completely lacks the expression of UBL1, a heterogeneous and variable expression pattern of the different metabolic enzymes was detected in RCC and normal renal epithelium. The highest differences in the expression levels were found for THIO in the RCC cell lines, which was 2-fold upregulated when compared to autologous normal kidney epithelium. Moreover, IFN-gamma treatment did not influence the constitutive expression of these metabolic enzymes. Thus, PROTEOMEX represents a valuable approach for the identification of metabolic enzymes which might be used as markers for the diagnosis of RCC.

Design of proteome-based studies in combination with serology for the identification of biomarkers and novel targets.

Recently proteome analysis has rapidly developed in the post‐genome era and is now widely accepted as a complementary technology to genetic profiling. The improvement in the technology of both two‐dimensional electrophoresis (2‐DE) analysis as well as protein identification has made proteomics a valuable and powerful tool to study human diseases. A combination of conventional proteome analysis with serology has been developed as a promising experimental approach for the discovery of serological markers in different malignancies. However, the design of proteome‐based studies has to be carefully performed since there are a number of critical needs for systematic and reproducible proteome analysis. In particular, the selection of tissue and its preparation represent an important step in proteome analysis. Besides the preparation of protein samples, the 2‐DE and protein identification is a further critical issue. So far proteome‐based technologies have been successfully used in tumor immunnology for the identification of tumor‐specific autoantigens. Similarly, this technology has been employed for the detection of virulence factors, antigens and vaccine candidates in infectious diseases, as well as for the identification of diagnostic and prognostic markers, suggesting that proteome‐based analysis is a promising tool for the identification of prognostic, diagnostic markers as well as for novel therapeutic targets which could be used for treatment of diseases. The integration of proteome‐based approaches with data from genomic or genetic profiling will lead to a better understanding of different diseases, which will then contribute to the direct translation of the research findings into clinical practice.

Down-regulation of the MHC class I antigen- processing machinery after oncogenic transformation of murine fibroblasts

Malignant transformation is often associated with genetic alterations providing tumor cells with mechanisms for escape from immune surveillance. Human and murine tumors of various origin as well as in vitro models of viral and oncogenic transformation express reduced levels of major histocompatibility complex (MHC) class I antigens resulting in decreased sensitivity to MHC class I‐restricted cytotoxic T lymphocyte (CTL)‐mediated lysis. We here investigate whether the suppressed MHC class I surface expression of ras‐transformed fibroblasts is due to dysregulation of the genes of the antigen‐processing machinery, the peptide transporters TAP‐1 and TAP‐2 and the proteasome subunits LMP‐2 and LMP‐7, and whether it can be restored by gene transfer. In comparison to parental NIH3T3 cells, the ras oncogenic transformants revealed reduced TAP and LMP mRNA expression and impaired function of these genes, leading to deficient peptide transport and peptide loading of MHC class I molecules resulting in instable expression of the MHC class I complex on the cell surface. Enhanced H‐2 surface expression due to stabilization of the MHC class I complex could be achieved by culturing ras transformants at low, unphysiological temperature (26 °C) or by loading these cells with either exogenous human β2‐microglobulin or MHC class I‐binding peptide alone or in combination. Furthermore, interferon‐γ treatment was capable to enhance the expression of TAP, LMP and MHC class I molecules in both parental as well as ras‐transformed fibroblasts. Stable transfection of the human TAP‐1 cDNA into ras transformants caused a partial reconstitution of the peptide transport and an enhancement of the MHC class I surface expression, whereas the level of MHC class I biosynthesis was not affected by TAP‐1 overexpression in parental cells. Together these results point to the existence of an association between oncogenic transformation and deficiencies in the MHC class I antigen‐restricted immunosurveillance, suggesting intervention strategies involving specific MHC class I‐binding peptides or transfection of the LMP and/or TAP genes to overcome the expression of the immune escape phenotype.