传染性肿瘤研究进展

传染性肿瘤是一类以活细胞形式在个体间异体传播的肿瘤。至今已发现并确定4种,即犬类生殖器传染性肿瘤(Canine transmissible venereal tumor, CTVT)、袋獾面部肿瘤(Tasmanian devil facial tumor disease, DFTD)、海螂血液传染性肿瘤(Soft-shell clams leukemia, SSCL)及仓鼠传染性肿瘤(Hamsters reticulum cell sarcoma, HRCS)。过去几十年,在细胞学、组织学、遗传学等方面的研究证明传染性肿瘤是以活细胞进行传播,CTVT是已知的最古老的哺乳动物体细胞系,DFTD来源于施旺细胞,两者均通过下调MHC基因表达逃避宿主免疫识别,而在SSCL中普遍存在一个转座子多拷贝数变异。近几年来,DFTD和CTVT基因组测序工作相继完成,有助于从全基因组水平研究传染性肿瘤的发生、传染和进化机制。本文总结了传染性肿瘤的研究进展,并展望了未来10年内传染性肿瘤的研究热点。     

Tumor-infiltrating lymphocyte secretion of IL-6 antagonizes tumor-derived TGF-beta 1 and restores the lymphokine-activated killing activity

IL-6 is a multifunctional cytokine that regulates cell growth, differentiation, and cell survival. Many tumor cells produce TGF-beta1, which allows them to evade CTL-mediated immune responses. IL-6 antagonizes TGF-beta1 inhibition of CD3 cell activation. However, whether IL-6 restores NK activity, which also is suppressed by TGF-beta1, is not known. We used canine transmissible venereal tumor (CTVT), which produces TGF-beta1, as a model to determine whether IL-6 restores lymphokine-activated killer (LAK) activity. During the progression phase, CTVT cells stop expressing MHC molecules. During the regression phase, the number of surface MHC molecules increases dramatically on about one-third of tumor cells. Tumor cells that stop expressing MHC should be targeted by NK cells. In this study, we found that TGF-beta1 secreted by CTVT cells suppressed LAK cytotoxicity. Interestingly, tumor-infiltrating lymphocytes (TIL) isolated from regressing CTVT secrete high concentrations of IL-6 and antagonize the anti-LAK activity of tumor cell TGF-beta1. TIL also produce IL-6 during progression phase, but the concentration is too low to block the anti-LAK activity of TGF-beta1. There is probably a threshold concentration of IL-6 needed to reverse TGF-beta1-inhibited LAK activity. In addition, in the absence of TGF-beta1, IL-6 derived from TIL does not promote the activity of LAK. This new mechanism, in which TIL manufacture high concentrations of IL-6 to block tumor TGF-beta1 anti-LAK activity, has potential applications in cancer immunotherapy and tumor prognosis.     

Canine transmissible venereal tumor – From general to molecular characteristics: A review

Cancer is a group of complex diseases resulting from the accumulation of genetic and epigenetic changes affecting control and activity of several genes, especially those involved in cell differentiation and growth processes, leading to an abnormal proliferation. When the disease reaches an advanced stage, cancer can lead to metastasis in other organs. Interestingly, recent studies have shown that some types of cancer spread not only through the body, but also can be transmitted among individuals. Therefore, these cancers are known as transmissible tumors. Among the three types of transmissible tumors that occur in nature, the canine transmissible venereal tumor (CTVT) is known as the oldest cancer in the world, since it was originated from a single individual 11 000 years ago. The disease has a worldwide distribution, and its occurrence has been documented since 1810. The CTVT presents three types of cytomorphological classification: lymphocytoid type, mixed type, and plasmacytoid type, the latter being chemoresistant due to overexpression of the ABCB1 gene, and consequently increase of the P-glycoprotein. More knowledge about the epidemiology and evolution of CTVT may help to elucidate the pathway and form of the global spread of the disease.     

Immunocharacterization of matrix metalloproteinase-2 and matrix metalloproteinase-9 in canine transmissible venereal tumors

Matrix metalloproteases (MMPs) are endogenous proteases that are responsible for degradation of extracellular matrix (ECM) proteins and cell surface antigens. The breakdown of ECM participates in the local invasion and distant metastases of malignant tumors. Canine transmissible venereal tumor (CTVT) is a naturally occurring contagious round cell neoplasm of dogs that affects mainly the external genitalia of both sexes. CTVT generally is a locally invasive tumor, but distant metastases also are common in puppies and immunocompromised dogs. We investigated the immune expressions and activities of MMP-2 and MMP-9 in CTVT. The presence of these enzymes in tumor cells and tissue homogenates was demonstrated by immunohistochemistry and western blotting. We used gelatin substrate zymography to evaluate the activities of MMP-2 and MMP-9 enzymes in tumor homogenates. We found that tumor cells expressed both MMP-2 and MMP-9. Electrophoretic bands corresponding to MMP-9 and MMP-2 were identified in immunoblots and clear bands that corresponded to the active forms of MMP-2 and MMP-9 also were detected in gelatin zymograms. Our study is the first detailed documentation of MMPs in CTVT.     

Analysis of canine transmissible veneral tumor genotypes using the D-loop region of mitochondrial DNA

Canine transmissible venereal tumor (CTVT) is the only neoplasm that can be spread among dogs through cell transplantation. Therefore, this tumor does not originate from host cell transformation. Although CTVT has a monophyletic origin, several studies have shown the presence of genetic diversity which was probably acquired after the development of its original clone. To investigate the genetic diversity of CTVT in Mexico and its relation with CTVTs disseminated worldwide, we sequenced a fragment of mitochondrial DNA in 50 tumor samples and matched blood samples from dog hosts from Mexico. We found ten new haplotypes in tumor samples, which were all distinct from their matched host. The TVT1 haplotype was the most frequent in our samples, suggesting that it could be the origin of the others. We found that haplotypes in Mexico and other countries are distributed in two well-defined clusters. Our data also suggest a close relationship among American haplotypes (Mexico, USA, Chile and Brazil). Interestingly, these American haplotypes were also closely related to Asian haplotypes. Taking into account the estimated timing of the origin of CTVT, we propose that CTVT might have originated in Asia; consequently, haplotypes currently present in America could descend from Asiatic lineages.     

The role of the Major Histocompatibility Complex in the spread of contagious cancers

Major Histocompatibility Complex (MHC) genes play a key role in immune response to infectious diseases, immunosurveillance, and self/nonself recognition. Matching MHC alleles is critical for organ transplantation, while changes in the MHC profile of tumour cells allow effective evasion of the immune response. Two unique cancers have exploited these features to become transmissible. In this review I discuss the functional role of MHC molecules in the emergence and evolution of Devil Facial Tumour Disease (DFTD) and Canine Transmissible Venereal Tumour (CTVT). High levels of genetic diversity at MHC genes play a critical role in protecting populations of vertebrate species from contagious cancer. However, species that have undergone genetic bottlenecks and have lost diversity at MHC genes are at risk of transmissible tumours. Moreover, evolution and selection for tumour variants capable of evading the immune response allow contagious cancers to cross MHC barriers. Transmissible cancers are rare but they can provide unique insights into the genetics and immunology of tumours and organ transplants.     

ORIGINS AND EVOLUTION OF A TRANSMISSIBLE CANCER

Canine transmissible venereal tumor (CTVT) is an infectious disease of dogs. Remarkably, the infectious agent is the cancerous cell itself. To investigate its origin and spread, we collected 37 tumor samples from four continents and determined their evolutionary relationships using microsatellite length differences and microarray-based comparative genomic hybridization (aCGH). The different tumors show very little microsatellite variation, and the pattern of variation that does exist is consistent with a purely asexual mode of transmission. Approximately one quarter of the loci scored by aCGH show copy number variation relative to normal dogs, again with little variation among different tumor samples. Sequence analysis of the RPPH1 gene indicates an origin from either dogs or wolves, and microsatellite analysis indicates that the tumor is more than 6000 years old, and perhaps originated when dogs were first domesticated. By contrast, the common ancestor of extant tumors lived within the last few hundred years, long after the first tumor. The genetic and genomic patterns we observe are typical of those expected of asexual pathogens, and the extended time since first origin may explain the many remarkable adaptations that have enabled this mammalian cell lineage to live as a unicellular pathogen.     

Analysis of HLA expression in human tumor tissues

Cancer cells can be detected and destroyed by cytotoxic T lymphocytes in many experimental tumor systems, and--as has been well-documented--in some human tumors. In humans however, most diagnosed tumors are not eliminated by T cells but grow steadily, invading and metastasizing until the host is destroyed. Evidence is accumulating that progressive tumor growth occurs not because the immune system is defective or deteriorated, but because the cancer cell is capable of developing a variety of strategies to escape immune recognition. In addition, cancer cells acquire new biological properties to generate invasive capacity in order to migrate and colonize new tissues. Major histocompatibility complex (MHC) antigens are molecules that are specialized in communicating with the T cell receptor and natural killer (NK) cell ligands. With the former, they use the interaction with peptides derived from processed cellular and exogenous proteins to monitor self and non-self status. With the latter, they determine the degree of activation and killing capacity of NK cells by interacting with NK receptors. Any change in the MHC profile of tumor cells (including classical and nonclassical MHC molecules) may therefore have a profound influence on the immune recognition and immune rejection of cancer cells. We have reviewed the data from our laboratory and other groups, and have presented a standardized procedure for analyzing the MHC profile of human tumors with special emphasis on the quality and laboratory use of the material obtained from microdissected tumor samples. Appropriate tissue processing is of particular relevance, since it is not possible to obtain tumor cell lines from most patients. Oncologists require rapid information on the MHC profile of the tumor if gene therapy is envisaged to restore normal MHC class I gene expression.     

Stromal cells and extracellular matrix components in spontaneous canine transmissible venereal tumour at different stages of growth

Stromal cells and extracellular matrix (ECM) components are important for tumour cell behaviour. Little is known about the role of stromal cells and ECM components in the progression and regression of spontaneous canine transmissible venereal tumour (CTVT). In this study, the stromal cell type was determined by immunohistochemical labelling with antibodies to desmin, vimentin and alpha-smooth muscle actin (alpha-SMA) during the progressive and regressive stages of spontaneous CTVT. The distribution of ECM components tenascin-C, chondroitin sulphate and versican were determined immunohistochemically, and hyaluronan distribution was determined using a biotinylated protein complex with specific affinity for hyaluronan. Stromal cells of tumours in both the progressive and regressive stage were positive for vimentin and negative for desmin. The number of stromal cells expressing alpha-SMA was significantly higher (P=0.001) in regressing tumours, than progressing tumours. These results suggest that the modulation of stromal cells that occurs during the regression of CTVT is similar to that occurring during wound healing. Tenascin-C was weakly expressed in the stroma of tumours in the progressive stage and in regions of the regressing tumours with tumour infiltrating lymphocytes (TILs), but intensely expressed in the stroma of tumours in late regressive stage. In addition, tenascin-C was also expressed in the cytoplasm of some tumour cells in the late regressive stage. A strong stromal tenascin-C intensity was significantly associated with regressing tumours (P=0.001). Strong stromal hyaluronan intensity and a high proportion of hyaluronan-positive tumour cells were significantly associated with progressing tumours (P=0.001). This suggests that hyaluronan is involved in the growth of the tumour. There was no significant difference in the expression of chondroitin sulphate and versican in progressing and regressing tumours.     

MHC class I antigens,immune surveillance,and tumor immune escape

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.     

Expression of class I histocompatibility antigens in neuroectodermal tumors is independent of the expression of a transfected neuroblastoma myc gene

We have evaluated the relationship between the neuronal myc gene (NMYC) and class I major histocompatibility complex (MHC) expression in human neuroblastoma (NB) tumor cell lines. Class I MHC surface Ag expression in NB cell lines varied from nearly undetectable to levels nearly as high as in a lymphoblastoid cell line. Class I MHC mRNA levels in NMYC-amplified NB cell lines were lower than levels observed in single copy NMYC NB cell lines. However, considerable variation in class I MHC surface Ag and mRNA expression was evident in NMYC-amplified cell lines. To determine directly whether NMYC might modulate class I MHC expression in NB, we transfected a plasmid containing a recombinant NMYC gene into two tumor cell lines derived from a NB and a related neuroepithelioma tumor. Constitutive overexpression of the recombinant NMYC gene produced no consistent change in class I MHC surface Ag or mRNA levels. To determine whether class I MHC expression might be developmentally regulated in adrenal medullary cells, the precursor cells of adrenal NB tumors, beta 2-microglobulin expression was measured in fetal and adult adrenal glands. beta 2-Microglobulin expression was not evident in the neuroblasts of a 24-wk-old fetal adrenal gland, whereas beta 2-microglobulin expression was present in the adult adrenal medulla. These data suggest that variation in class I MHC expression among NB cells may reflect the developmental stage at which neuroblasts were arrested during tumorigenesis.     

Tumor infiltrating leukocytes (tils) during progressive tumor growth and BCG-mediated tumor regression

Tumor regression was induced by intralesional injection with BCG, 7 days after inoculation of line 10 hepatocellular carcinoma cells into strain 2 guinea pigs. Tumor-infiltrating leukocytes (TILS) were characterized immunohistochemically with 11 monoclonal antibodies (MoAbs) during the induction phase of line 10-immunity, and during immune-mediated regression of the tumor, at days 12 and 28 after tumor cell inoculation, respectively. At day 5 after BCG-injection (day 12 after tumor cell inoculation), there were no major differences between the TIL subpopulations of the BCG-treated and untreated tumors. The TILS were mainly T-cells, as identified by MoAbs against Pan T-cells (CT5), T-cytotoxic/suppressor cells (CT6) and T-helper/inducer cells (H155). A limited number of macrophages was also present. However, at day 21 after BCG-treatment (28 days after tumor cell inoculation), the fibrous stroma was increased dramatically in most of the BCG-treated tumors, and as a result, the tumor cell islets were smaller than in control tumors. In the BCG treated tumors, the numbers of T-cells and macrophages were increased. In growing and regressing tumors, MHC class I and II antigens were strongly expressed in TILS and in the tumor stroma. Line 10 tumor cells prior to inoculation expressed no MHC class I or II antigens. In the centers of the tumor islets at days 12 and 28, expression of these antigens was not found. However, MHC class I and II antigens were expressed on tumor cells at sites where they lay close to the fibrous stroma or TILS. This observation was made in progressively growing tumors and was most apparent in BCG-treated tumors.     

A central role for death receptor-mediated apoptosis in the rejection of tumors by NK cells

NK cells provide a line of defense against tumors and virus-infected cells that have lost the expression of one or more MHC class I isoforms. Here, we investigate whether inhibitors of apoptosis can block the rejection of tumors mediated by NK cells, by introducing the long form of Fas-associated death domain-like IL-1beta-converting enzyme-associated inhibitory protein (FLIP(L)) and poxvirus cytokine response modifier A (CrmA) into the MHC class I-deficient T lymphoma cell line RMA-S. RMA-S cells do not normally express Fas in vitro, and it was previously postulated that the rejection of these tumors by NK cells is strictly perforin dependent. We show that perforin-deficient NK cells directly mediate Fas up-regulation on RMA-S cells and thereafter kill the cells in a Fas-dependent manner, and that RMA-S FLIP(L) and RMA-S CrmA are protected from such killing. When injected in immunocompetent recipients, RMA-S cells up-regulate Fas, rendering in vivo-passed mock-transduced cells sensitive to Fas-mediated apoptosis. Moreover, RMA-S FLIP(L) and RMA-S CrmA cells establish aggressive tumors, in contrast to RMA-S mock cells that are rejected. These results demonstrate that FLIP(L) and CrmA function as tumor progression factors by protecting MHC class I-deficient tumors from rejection mediated by NK cells. Moreover, our data indicate that death receptor-mediated apoptosis has a more prominent role in the clearance of NK-sensitive tumors than previously suggested.     

The escape of cancer from T lymphocytes: immunoselection of MHC class I loss variants harboring structural-irreversible “hard” lesions

The discovery of tumor antigens recognized by T lymphocytes has stimulated the development of a variety of cancer treatment protocols aimed at enhancing antitumor-specific T cell responses and tumor rejection. However, immunotherapy-mediated regression of established tumors and clearly positive clinical response to such treatment has not been achieved yet despite the induction of T cells directed against tumor antigens. The failure of the modern immunotherapy protocols can be explained by different tumor escape mechanisms that have been defined in various types of malignancy. The loss or downregulation of MHC class I antigens in tumor cells is one of the best analyzed mechanisms. In this review, we show experimental evidence obtained in our laboratory on human tumors and in a mouse cancer model suggesting that the molecular mechanism responsible for the MHC class I alteration in tumor cells might have a crucial impact on tumor recovery of normal H-2/HLA expression during the natural history of tumor development or after immunotherapy. When the preexisting molecular lesion underlying tumor MHC class I alteration is reversible (regulatory or soft), class I expression can be recovered leading to regression of tumor lesion. In contrast, if the HLA class I alteration is irreversible in nature (structural or hard), the lesion will progress killing the host. This is a new vision of the role of MHC class I alteration in tumors that can explain the failure of immunotherapy in a variety of different clinical protocols.     

Characterization of defective CD4-CD8- T cells in murine tumors generated independent of antigen specificity

Immune-based therapy confers limited benefits to hosts bearing late-stage tumors. Mounting evidence points to local suppression of T cell function as the most substantial barrier to effective antitumor immunity in hosts with large tumor burdens. Despite this, events responsible for locally defective T cells and immune suppression in tumors remain unclear. We describe in this study a predominant T cell population localized within two murine tumors that is characterized by expression of apoptotic markers and TCRalphabeta/CD3, but not CD4, CD8, or NK-associated markers. These defective cells resembled double negative (DN) T cells in lpr mice, harbored defects in the expression of T cell signaling molecules, and produced the anti-inflammatory cytokine, IL-10. Conditions known to increase or decrease the accumulation of lpr DN T cells had corresponding effects on local DN tumor infiltrating lymphocyte (TIL) levels and inversely impacted host survival. Adoptive transfer into s.c. tumors demonstrated that naive CD8(+) T cells were highly susceptible to becoming DN TIL, and local supplementation of tumors with nontumor Ag-bearing MHC class I-expressing fibroblasts decreased both this susceptibility and endogenous DN TIL levels. These findings identify a major defective T cell population with suppressive potential within tumors. The data also suggest that local T cell defectiveness is controlled by the tumor environment independent of cognate Ag specificity per se. Decreasing defective DN TIL levels by increasing noncognate peptide MHC class I availability, or modulating TCR or cytokine signaling may facilitate host survival by bolstering endogenous immunity to late-stage tumors, and may help improve therapeutic tumor vaccines.     

Rejection of mouse sarcoma cells after transfection of MHC class II genes

Th cells are stimulated by peptide Ag presented in the context of MHC class II molecules. We have reasoned that immune responses against tumors may be more efficient if tumor cells were class II Ag positive, and thereby able to directly function as APC to stimulate tumor-specific Th cell proliferation. We have tested this hypothesis by using DNA-mediated gene transfer to generate syngeneic MHC class II Ag-expressing mouse Sal sarcoma cells (Sal/Ak transfectants). Autologous A/J mice challenged i.p. or s.c. with Sal/Ak transfectants do not develop tumors, whereas A/J mice challenged with the class II negative parental Sal tumor have a high tumor incidence. Furthermore, immunization of the autologous host with Sal/Ak transfectants completely protects against subsequent challenge with wild-type Sal cells. MHC class II-expressing tumor cells, therefore, stimulate an improved tumor-specific immune response, and the immunity is cross-reactive with the class II negative tumor. Inasmuch as the transfected MHC class II gene product is not functioning as a target molecule for autologous tumor rejection, the improved immunogenicity of the Sal/Ak cells is probably due to stimulation of a tumor-specific Th cell population. The increased immunogenicity of Sal/Ak cells is, therefore, probably the result of direct presentation of Sal tumor-associated Ag in the context of tumor cell MHC class II molecules to Th lymphocytes. These studies demonstrate that induction of tumor cell MHC class II Ag expression is a potential strategy for tumor-specific immunotherapy, and suggest that tumor immunity may be enhanced by improved Th cell generation.