Oncogenic transformation in human and experimental animals is not necessarily followed by the appearance of a tumor mass. The immune system of the host can recognize tumor antigens by the presentation of small antigenic peptides to the receptor of cytotoxic T-lymphocytes (CTLs) and reject the nascent tumor. However, cancer cells can sometimes escape these specific T-cell immune responses in the course of somatic (genetic and phenotypic) clonal evolution. Among the tumor immune escape mechanisms described to date, the alterations in the expression of major histocompatibility complex (MHC) molecules play a crucial step in tumor development due to the role of MHC antigens in antigen presentation to T-lymphocytes and the regulation of natural killer cell (NK) cell function. In this work, we have (1) updated information on the mechanisms that allow CTLs to recognize tumor antigens after antigen processing by transformed cells, (2) described the altered MHC class I phenotypes that are commonly found in human tumors, (3) summarized the molecular mechanisms responsible for MHC class I alteration in human tumors, (4) provided evidence that these altered human leukocyte antigens (HLA) class I phenotypes are detectable as result of a T-cell immunoselection of HLA class I-deficient variants by an immunecompetent host, and (5) presented data indicating the MHC class I phenotype and the immunogenicity of experimental metastatic tumors change drastically when tumors develop in immunodeficient mice.
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.
ABSTRACT:It is generally accepted that human and experimental tumor cells can lose major histocompatibility complex (MHC) class I molecules. These human leukocyte antigen (HLA) losses are detected when the primary tumor breaks the basal membrane, invades the surrounding tissues, and starts to metastasize. These altered HLA class I phenotypes probably constitute the major tumor escape mechanism facing anti-tumor T-cell mediated responses. Thus, it is important to characterize these phenotypes in clinical tumor samples, analyze the mechanism(s) responsible for them, and counsel patients before and during peptide anti-cancer immunotherapy. The present paper summarizes the most relevant altered HLA class I phenotypes found in human tumor samples, indicates their frequency, and outlines the mechanisms implicated. This review also points out that the natural killer (NK) escape mechanism of HLA class I deficient cancer cells is yet to be defined. Knowledge accumulated to date reveals that HLA class I molecules are an important crossroad in tumor immunology. Human Immunology 61, 65-73 (2000).
We investigated whether detection of cytokeratin-positive (CK؉) cells in the peripheral blood (PB) of breast cancer patients before chemotherapy could be a prognostic factor. Blood from a total of 92 breast cancer patients was evaluated for the presence of CK؉ cells. Blood samples were collected before chemotherapy. Patients entered in the study included: neoadjuvant (n ؍ 25), adjuvant (n ؍ 42) and metastatic (n ؍ 25). Blood samples (10 ml) were centrifuged using a double density-gradient to recovering the mononuclear cell (MNC) and granulocyte cell (GC) fractions. Subsequently, positive immunomagnetic cell separation was carried out to isolating CK؉ cells. The enriched cell fraction was cytocentrifuged and then immunocytochemically labeled using an anti-cytokeratin antibody. Our results indicated that breast tumor cells sediment with both MNC and GC fractions. We showed that using the method we present, the detection of CK؉ cells in PB before starting the chemotherapy in breast cancer patients was significantly correlated with both progression-free survival (p ؍ 0.058) and overall survival (p ؍ 0.003). In conclusion, the present study suggests that detection of CK؉ cells in PB before chemotherapy might identify breast cancer patients with poor prognosis. Breast cancers have been shown to shed tumor cells into the circulation at the earliest stages of primary tumor development. It is accepted that it is the early hematogenous dissemination of the tumor that decides the patient's fate. Fehm et al. 1 have reported that circulating epithelial cells in breast cancer patients are malignant. The potential of circulating tumor cells to form metastases in vivo has been reported by Pretlow et al. 2 They showed the capacity to induce metastases in nude mice from tumor cells taken directly from the peripheral blood (PB) of patients. Thus, the early detection of circulating tumor cells may have important therapeutic and prognostic implications. It could be an independent prognostic factor that could identify the patients who are most likely to benefit from adjuvant therapy. Immunological and molecular methods have been used for detecting circulating tumor cells, 3 but it has not been possible to standardize a method internationally. This could explain the contradictory results obtained by different groups.We investigated whether detection of cytokeratin-positive (CKϩ) cells in PB of breast cancer patients before chemotherapy could be a prognostic factor. Cytokeratin is a valuable marker for breast tumor cell in PB. Blood from a total of 92 breast cancer patients was evaluated for the presence of CKϩ cells. Blood samples were collected before chemotherapy just when the patients were included in this study. Patients entered in the study included: neoadjuvant (n ϭ 25), adjuvant (n ϭ 42) and metastatic (n ϭ 25). Correlation of CKϩ cells with patient characteristics and with well established prognostic parameters were carried out. We have used an immunomagnetic separation procedure for the detection of circulating tumo...
Background: Phytopharmacological studies of different Calendula extracts have shown antiinflamatory, anti-viral and anti-genotoxic properties of therapeutic interest. In this study, we evaluated the in vitro cytotoxic anti-tumor and immunomodulatory activities and in vivo anti-tumor effect of Laser Activated Calendula Extract (LACE), a novel extract of the plant Calendula Officinalis (Asteraceae).
Tumor dormancy is a clinical phenomenon related to immune equilibrium during cancer immunoediting. The mechanisms involved in dormant metastases are poorly understood due to the lack of preclinical models. Here, we present a nontransgenic mouse model in which spontaneous metastases remain in permanent immunomediated dormancy with no additional antitumor treatment. After the injection of a GR9-B11 mouse fibrosarcoma clone into syngeneic BALB/c mice, all animals remained free of spontaneous metastases at the experimental endpoints (3-8 months) but also as long as 24 months after tumor cell injection. Strikingly, when tumor-bearing mice were immunodepleted of T lymphocytes or asialo GM1-positive cells, the restraint on dormant disseminated metastatic cells was relieved and lung metastases progressed. Immunostimulation was documented at both local and systemic levels, with results supporting the evidence that the immune system was able to restrain spontaneous metastases in permanent dormancy. Notably, the GR9-B11 tumor clone did not express MHC class I molecules on the cell surface, yet all metastases in immunodepleted mice were MHC class I-positive. This model system may be valuable for more in-depth analyses of metastatic dormancy, offering new opportunities for immunotherapeutic management of metastatic disease. Cancer Res; 74(7); 1958-68. Ó2014 AACR.
Previous reports from our group indicated that the MHC class I phenotype of metastatic lung colonies produced by a mouse fibrosarcoma tumor clone (B9) were, depending on the immune status of the host, MHC class I negative in immunocompetent mice and MHC class I positive in immunodeficient athymic nude/nude mice. Now we report the identification of the molecular alterations responsible for the changes of MHC class I molecules in both situations. Metastatic nodes were analyzed for the mRNA level of H-2 class I and 2-microglobulin genes, and several gene components of the major histocompatibility complex (MHC) class I antigenprocessing machinery (APM). These included the genes coding for the low-molecular-weight proteins LMP2, LMP7, LMP10, the transporter associated with antigen processing (TAP-1, TAP-2), and calnexin, calreticulin, tapasin, PA-28-␣, PA-28-, ERP-59 and ER-60. Analyses with RT-PCR showed that TAP-1, TAP2, LMP-2, LMP7, LMP10, tapasin and calnexin mRNA specific for these genes was absent in metastases produced in immunocompetent mice. In contrast, similar techniques with mRNA preparations obtained from metastatic nodes from immunodeficient mice showed that the mRNA expression level of these genes was highly positive. Interestingly, the MHC class I-positive or negative phenotypes of the metastatic colonies correlated with in vivo immunogenicity. H-2 positive metastasis grew more slowly than the H-2 negative ones when injected intrafootpat in syngeneic immunocompetent animals and were finally rejected. These results provide evidence of the role of T cells in immune surveillance against tumors and identify a mechanism targeted by antitumor T lymphocytes to generate MHC class I-negative tumor escape variants.
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