Impaired migration of IgA-secreting cells to colon adenocarcinomas

Local inflammation is a strong risk factor for the development of gastrointestinal adenocarcinomas. Mucosal regulatory T cells and IgA-secreting cells both contribute to reduce inflammatory responses, and their recruitment to tissues is dependent on local production of chemokines. More specifically, IgA-secreting cells are recruited to mucosal tissues by CCL28 signalling through CCR10. Here, we examined the recruitment of IgA-secreting plasma cells to tumor-associated mucosa in patients suffering from colon adenocarcinoma. Flow cytometric analyses of single cell suspensions from tumor-associated and unaffected colon mucosa showed a marked decrease in CD19⁺CD38^highIgA⁺ plasmablasts in the tumor-associated mucosa, while the total frequencies of B and T cells were similar. This finding was confirmed in ELISPOT assays, demonstrating a 64 % reduction in the frequencies of IgA-secreting cells among cells from the tumor-associated mucosa. The few IgA⁺ plasmablasts present in the tumor did not express CCR10, and functional migration assays demonstrated that IgA-secreting cells from tumor-associated mucosa did not migrate in response to CCL28. Taken together, our results show an impaired migration of IgA-secreting cells to colon tumors, presumably caused by a decreased production of CCL28 in the tumor. The lack of local IgA antibodies may lead to impaired barrier function and increased bacterial colonization, driving further inflammatory responses and promoting tumor growth.     

Mimotopes of tumor-associated T-cell epitopes for cancer vaccines determined with combinatorial peptide libraries

Cytotoxic T-cells are the most important effector cells in immune responses against tumors. The identification of tumor-associated epitopes for these cells, therefore, has become a key aspect of the development of cancer vaccines. Here, we describe a new approach to the determination of tumor-associated T-cell epitopes which employs combinatorial peptide libraries with singly defined sequence positions in a randomized context. The analysis of the responses of a T-cell clone to these libraries yields the amino acid constituents of the epitope which can be combined to obtain mimotopes that are suitable as vaccine antigens for the induction of tumor-specific responses.     

Characterization of a cloned ultraviolet radiation (UV)-induced suppressor T cell line that is capable of inhibiting anti-UV tumor-immune responses

Ultraviolet radiation (UV) is a potent carcinogen for the induction of skin tumors. In this regard, UV represents a unique carcinogenic agent, in that depending on the dosage and conditions of administration it can function as either a complete carcinogen, a carcinogenic promoting agent, or an immunologic modulator of anti-tumor rejection responses. The immunologic modulatory activity of UV has been demonstrated in numerous studies. These studies have shown that subcarcinogenic doses of UV induce a population of suppressor T lymphocytes (Ts cells) that allow for the emergence and progression of UV-induced tumors. Although the phenotypic and functional properties of these cells have been established, it was unclear as to whether the UV-induced Ts cell population consisted of multiple Ts cell clones able to recognize a range of unique tumor antigens or a limited number of Ts cell clones with functional specificity directed toward a common tumor-associated antigen (TAA). To address this question, an interleukin 2-dependent, UV-induced cloned Ts cell line was derived, by limiting dilution without exogenous antigen stimulation, from the splenic T cell population of a C3H mouse that had been exposed to a subcarcinogenic dose of UV. This Ts cell line, designated UV2.10, was selected for its ability to suppress the in vitro differentiation of cytotoxic T cells from the draining lymph nodes of UV-induced tumor-immune mice. When transferred into non-UV-irradiated syngeneic mice, which normally reject a UV-induced tumor implant, the UV2.10 cells rendered their hosts susceptible to the growth of a battery of UV-induced tumors. Although capable of suppressing in vitro and in vivo UV-induced tumor-immune responses, UV2.10 cells did not inhibit the elicitation of contact hypersensitivity responses, the rejection of allogeneic skin grafts, responses, the rejection of allogeneic skin grafts, or the rejection of allogeneic UV-induced tumors. These data suggest that the cloned UV2.10 Ts cell line possesses functional antigenic specificity that may be limited to the regulation of immune responses that are directed toward the TAA expressed by syngeneic UV-induced tumors. Employing monoclonal antibodies and FACS analysis, the cell surface phenotype of the UV2.10 cell line was determined to be: Thy-1.2+, Lyt-1-, Lyt-2+/- (dim), L3T4a-, I-A/E-, and I-J+. This cell surface phenotype is indicative of a suppressor T cell. These data lend further support to the hypothesis that the UV-induced Ts cell population is clonal in nature and functions through its ability to recognize a common TAA(s) that appears to be expressed by virtually all UV-induced tumors.     

Special symposium: In vitro plant recalcitrance loss of plant organogenic totipotency in the course of In vitro neoplastic progression

Summary The aptitude for organogenesis from normal hormone-dependent cultures very commonly decreases as the tissues are serially subcultured. The reasons for the loss of regenerative ability may vary under different circumstances: genetic variation in the cell population, epigenetic changes, disappearance of an organogenesis-promoting substance, etc. The same reasons may be evoked for the progressive and eventually irreversible loss of organogenic totipotency in the course of neoplastic progressions from hormone-independent tumors and hyperhydric teratomas to cancers. As in animal cells, plant cells at the end of a neoplastic progression have probably undergone several independent genetic accidents with cumulative effects. They indeed are characterized by atypical biochemical cycles from which they are apparently unable to escape. The metabolic changes are probably not the primary defects that cause cancer, rather they may allow the cells to survive. How these changes, namely an oxidative stress, affect organogenesis is not known. The literature focuses on somatic mutations and epigenetic changes that cause aberrant regulation of cell cycle genes and their machinery.     

Tumor microenvironment: Bone marrow-mesenchymal stem cells as key players

Tumor progression is a multistep phenomenon in which tumor-associated stromal cells perform an intricate cross-talk with tumor cells, supplying appropriate signals that may promote tumor aggressiveness. Among several cell types that constitute the tumor stroma, the discovery that bone marrow-derived mesenchymal stem cells (BM-MSC) have a strong tropism for tumors has achieved notoriety in recent years. Not only are the BM-MSC recruited, but they can also engraft at tumor sites and transdifferentiate into cells such as activated fibroblasts, perivascular cells and macrophages, which will perform a key role in tumor progression. Whether the BM-MSC and their derived cells promote or suppress the tumor progression is a controversial issue. Recently, it has been proposed that proinflammatory stimuli can be decisive in driving BM-MSC polarization into cells with either tumor-supportive or tumor-repressive phenotypes (MSC1/MSC2). These considerations are extremely important both to an understanding of tumor biology and to the putative use of BM-MSC as “magic bullets” against tumors. In this review, we discuss the role of BM-MSC in many steps in tumor progression, focusing on the factors that attract BM-MSC to tumors, BM-MSC differentiation ability, the role of BM-MSC in tumor support or inhibition, the immunomodulation promoted by BM-MSC and metastatic niche formation by these cells.     

Matricellular proteins and inflammatory cells: A task force to promote or defeat cancer?

In the last years it became clear that the tumor microenvironment plays a major role in neoplastic growth. Proteins secreted either by the malignant cells or by the tumor-associated stromal cells act as extracellular signal transductors, orchestrating tumor progression. Sentinel cells of the innate immune system patrol the different organs and have proven either to promote tumor growth or induce tumor suppression. In recent years, members of the matricellular family of extracellular proteins were shown to be involved in different aspects of the inflammatory response during tumor development, although in contradictory ways. In this review we discuss the evidence available up to date that relates matricellular proteins with the regulation of the inflammatory response and tumor progression.     

The architect who never sleeps: Tumor-induced plasticity

Tumor cell plasticity is an event that has been observed in several malignancies. In fact, most of the solid tumors are characterized by cellular heterogeneity and undergo constant changes as the tumor develops. The increased plasticity displayed by these cells allows them to acquire additional properties, enabling epithelial-mesenchymal transitions, dedifferentiation and the acquisition of stem cell-like properties. Here we discuss the particular importance of an inflammatory microenvironment for the bidirectional control of cellular plasticity and the potential for therapeutic intervention.     

Role Of Immature Myeloid Cells in Mechanisms of Immune Evasion In Cancer

Tumor affects myelopoiesis by inhibiting the process of differentiation/maturation of antigen-presenting cells from their myeloid precursors and by stimulating an accumulation of immature myeloid cells in cancer patients and tumor-bearing mice. These immature myeloid cells can contribute greatly to tumor progression and promote tumor evasion from immune attack: i) by inhibiting development of adaptive immune responses against tumor in lymphoid organs; ii) by migrating into tumor site and differentiating there into highly immune suppressive tumor-associated macrophages. Immature myeloid cells and tumor-associated macrophages utilize different JAK/STAT signaling pathways and different mechanisms to control T cell responses, which include increased production of TGF-beta, reactive oxygen species, peroxynitrites, as well as enhanced L-arginine metabolism. Understanding of precise mechanisms, which tumors use to affect differentiation of APC from myeloid cell precursors and inhibit T cell responses, could help to develop new approaches for cancer therapy and substantially improve efficiency of existing cancer vaccination strategies.     

Repeated administration of cytosine-phosphorothiolated guanine-containing oligonucleotides together with peptide/protein immunization results in enhanced CTL responses with anti-tumor activity

The development of therapeutic anti-cancer vaccines designed to elicit CTL responses with anti-tumor activity has become a reality thanks to the identification of several tumor-associated Ags and their corresponding peptide T cell epitopes. However, peptide-based vaccines, in general, fail to elicit sufficiently strong CTL responses capable of producing therapeutic anti-tumor effects (i.e., prolongation of survival, tumor reduction). Here we report that repeated administration of synthetic oligonucleotides containing foreign cytosine-phosphorothiolated guanine (CpG) motifs increased 10- to 100-fold the CTL response to immunization with various synthetic peptides corresponding to well-known T cell epitopes. Moreover, repeated CpG administration allowed the induction of CTL to soluble protein even in the absence of additional adjuvant. Our results indicate that the potentiating effect of CpG in CTL responses required the participation of Th lymphocytes. Repeated CpG administration resulted in overt splenomegaly and lymphadenopathy with a significant increase in the numbers of CTL precursors and dendritic cells. Protein vaccination in combination with repeated CpG therapy was effective in delaying tumor cell growth and extending survival in mice bearing melanoma tumors. These findings support the contention that repeated administration of CpG-oligonucleotides enhances the effect of peptide and protein vaccines leading to potent anti-tumor responses, presumably through the induction of Th1 and dendritic cells, which are essential for optimal CTL responses. The immunostimulatory properties of CpG motifs may be key in inducing a consistent long term immunity to tumor-associated Ags when using peptides or proteins as T cell-inducing vaccines.     

Characterization of human CD4 helper T cell responses against Aurora kinase A

Aurora kinase A (Aurora-A) is a cell cycle-associated serine–threonine kinase that is overexpressed by various types of cancer and is highly associated with poor prognosis. Since the expression of Aurora-A in normal tissues has been shown to be significantly lower as compared to tumor cells, this protein is being considered as a potential tumor-associated antigen for developing immunotherapies. The goal in the present study was to identify CD4 helper T lymphocyte (HTL) epitopes for Aurora-A for the design of T cell-based immunotherapies against Aurora-A-expressing tumors. Synthetic peptides corresponding to potential HTL epitopes were identified from Aurora-A and used to stimulate CD4 T lymphocytes in vitro to generate antigen-specific HTL clones that were evaluated for antigen specificity, MHC restriction and for their ability to interact with Aurora-A-expressing tumor cells. The results show that two peptides (Aurora-A_161–175 and Aurora-A_233–247) were effective in generating HTL responses that were restricted by more than one MHC class II allele (i.e., promiscuous responses). The CD4 HTL clones were able to directly recognize Aurora-A-expressing tumor cells in an antigen-specific and MHC class II-restricted manner and some of the clones displayed cytolytic activity toward Aurora-A + tumor cells. Both of these peptides were capable of stimulating in vitro T cell responses in patients with bladder cancer.     

Color-coded fluorescence imaging of tumor-host interactions

Fluorescent proteins have the properties of being very bright with high quantum yield and are available in many colors. Tumor-host models consist of transgenic mice expressing green fluorescent protein (GFP) in essentially all cells and tissues or expressing GFP selectively in specific tissues such as blood vessels. Particularly useful are the corresponding nude mice transgenic for GFP expression, as they can accept human tumors. When tumor cells expressing red fluorescent protein are implanted in mice expressing GFP, various types of tumor-host interactions can be observed, including those involving host blood vessels, lymphocytes, tumor-associated fibroblasts, macrophages, dendritic cells and others. The 'color-coded' tumor-host models enable imaging and therefore a deeper understanding of the host cells involved and their function in tumor progression. Approximately 4-8 weeks are needed for these procedures.     

Tumor cell- and microenvironment-specific roles of cysteine cathepsins in mouse models of human cancers

The human genome encodes for 11 papain-like endolysosomal cysteine peptidases, collectively known as the cysteine cathepsins. Based on their biochemical properties and with the help of experiments in cell culture, the cysteine cathepsins have acquired a reputation as promotors of progression and metastasis of various cancer entities. However, tumors are known to be complex tissues in which non-cancerous cells are also critical for tumorigenesis. Here we discuss the results of the intense investigation of cathepsins in mouse models of human cancers. We focus on models in immunocompetent mice, because only such models allow for analysis of cathepsins in a fully functional tumor microenvironment. An important outcome of those studies was the identification of cancer-promoting cathepsins in tumor-associated macrophages. Another interesting outcome of these animal studies was the identification of a homeostatic tumor-suppressive role for cathepsin L in skin and intestinal cancers. Taken together, these in vivo findings provide a basis for the use of cysteine cathepsins as therapeutic targets, prodrug activators, or as proteases for imaging tumors.     

Roles of tumor suppressors in regulating tumor-associated inflammation

Loss or silencing of tumor suppressors (TSs) promotes neoplastic transformation and malignant progression. To date, most work on TS has focused on their cell autonomous effects. Recent evidence, however, demonstrates an important noncell autonomous role for TS in the control of tumor-associated inflammation. We review evidence from clinical data sets and mouse model studies demonstrating enhanced inflammation and altered tumor microenvironment (TME) upon TS inactivation. We discuss clinical correlations between tumor-associated inflammation and inactivation of TS, and their therapeutic implications. This review sets forth the concept that TS can also suppress tumor-associated inflammation, a concept that provides new insights into tumor–host interactions. We also propose that in some cases the loss of TS function in cancer can be overcome through inhibition of the resulting inflammatory response, regardless whether it is a direct or an indirect consequence of TS loss.     

Minireview: Inflammation: an instigator of more aggressive estrogen receptor (ER) positive breast cancers

Approximately 75% of breast tumors express the estrogen receptor (ER), and women with these tumors will receive endocrine therapy. Unfortunately, up to 50% of these patients will fail ER-targeted therapies due to either de novo or acquired resistance. ER-positive tumors can be classified based on gene expression profiles into Luminal A- and Luminal B-intrinsic subtypes, with distinctly different responses to endocrine therapy and overall patient outcome. However, the underlying biology causing this tumor heterogeneity has yet to become clear. This review will explore the role of inflammation as a risk factor in breast cancer as well as a player in the development of more aggressive, therapy-resistant ER-positive breast cancers. First, breast cancer risk factors, such as obesity and mammary gland involution after pregnancy, which can foster an inflammatory microenvironment within the breast, will be described. Second, inflammatory components of the tumor microenvironment, including tumor-associated macrophages and proinflammatory cytokines, which can act on nearby breast cancer cells and modulate tumor phenotype, will be explored. Finally, activation of the nuclear factor κB (NF-κB) pathway and its cross talk with ER in the regulation of key genes in the promotion of more aggressive breast cancers will be reviewed. From these multiple lines of evidence, we propose that inflammation may promote more aggressive ER-positive tumors and that combination therapy targeting both inflammation and estrogen production or actions could benefit a significant portion of women whose ER-positive breast tumors fail to respond to endocrine therapy.     

Bad seeds produce bad crops: A single stage-process of breast carcinogenesis

It is a commonly held belief that human breast carcinogenesis is a multi-stage-process, and that progression from pre-invasion to invasion is triggered by overproduction of proteolytic enzymes that cause degradation of the basement membrane. These assumptions are hard to reconcile with two critical facts: (1) a subset of normal appearing tissues share a similar immunohistochemical or genetic profile with malignant counterparts and (2) a vast majority of in situ tumors express high levels of proteolytic enzymes, while only 10–30% of untreated in situ tumors progress to invasion. These facts argue that alternative pathways may play more direct roles in tumor progression and invasion in some cases.Loss of the myoepithelial (ME) cell layer is the most distinct sign associated with invasion. Our recent studies revealed that a subset of normal appearing duct clusters harbored a high frequency of focal ME cell layer disruptions (FMCLD). The residual ME cells of these duct clusters had significantly reduced expression of tumor suppressors, elevated rates of apoptosis and infiltration of immunoreactive cells, and the epithelial cell clusters overlying these disruptions had a significantly elevated frequency of tumor-associated phenotypes.Based on these and other findings, we have proposed that these morphologically normal appearing duct clusters are derived from genetically damaged stem cells, and could progress directly to invasion or metastasis through two pathways: (1) the entire ME basal cell layer is gradually degenerated or disappeared, allowing direct physical contact of epithelial cells with stromal and immunoreactive cells, which induce invasive properties without morphological alterations and (2) ER negative cell clusters overlying FMCLD retain the potential for multi-lineage differentiation that continuously proliferate and provide new cells and their own vascular structures for invasion and metastasis.     

Biochemical analysis of metastasis-related Ax actin in B16 mouse melanoma cells after chemical reversional modulation and of tumor progression-related A' actin in the ontogeny of human malignant melanoma

To examine the correlation between tumor metastasis and Ax actin in mouse melanoma and between tumor progression and A'.actin in human melanoma and further to investigate whether or not it is a generally existing principle, we studied the effects of reversion agents, which distinctly decrease metastatic ability of melanoma cells, on the appearance of Ax actin. Will an induced decrease in metastasis of established highly metastatic B16-F10 mouse melanoma cells cause the appearance of Ax actin? We also examined the appearance of A' actin in eight human benign pigment cell tumors and nine human malignant melanoma tissues or cells in relation to tumor progression. In vitro treatment of B16-F10 cells with each of these agents suppressed metastatic ability of the cells injected intravenously into syngenic mice; however, none of the treated cells represented Ax actin in vitro. These results suggest that the appearance of Ax actin may be a result of long-term tumor cell progression leading to changes in gene level, but because the treatments with these agents were only carried out over a short period, they could not effect changes in gene level; thus, Ax actin appearance remained unchanged. Appearance of A' actin was detected only in human benign pigment cell tumors such as nevus cell nevi, but not in malignant melanomas, which were also formed in a long period of tumor progression in vivo. These results suggest that A' actin is a clinically useful marker to determine the prognosis and level of tumor progression of human pigment cell tumors.     

Monocyte chemotactic cytokine gene transfer modulates macrophage infiltration, growth, and susceptibility to IL-2 therapy of a murine melanoma.

Tumor-derived chemotactic factors have been identified and suggested to play a role in the regulation of macrophage infiltration in neoplastic tissues. The present study was designed to assess the in vivo relevance of a tumor-derived chemotactic factor molecularly identified as monocyte chemotactic protein (MCP; alternative designations are JE and MCAF) by gene transfer in a murine melanoma. After gene transfer, MCP-producing melanoma clones showed a marked (twofold) increase in the percentage of tumor-associated macrophages compared with control clones and with the parent line: for instance, the percentage of tumor-associated macrophages was 20.9 +/- 1.5, 29.4 +/- 2.3, and 47.6 +/- 2.5 for the parent line, the control V14 clone, and the MCP-producing L12 clone, respectively. MCP-producing cells were tumorigenic but exhibited a slower growth rate in vivo (e.g., doubling time of 2.9 and 6.6 days for the control V14 and the MCP-producing L12 clone, respectively) with a prolongation of survival time. The in vitro growth rate of melanoma clones was unaffected by MCP gene transfer. The same difference between MCP-producing and control cells, in terms of macrophage infiltration and growth rate, was detected after implantation in athymic mice. Whereas the in vivo growth rate of MCP-expressing tumors was slower, after i.m. inoculation of small cell numbers (10(2) cells) MCP-producing cells were slightly, but significantly, more tumorigenic. Local administration of IL-2 had modest, but definite, antitumor activity in this model; MCP-producing cells were less susceptible to local IL-2 immunotherapy. These results demonstrate that a tumor-derived chemotactic cytokine can indeed play a role in the regulation of mononuclear phagocyte recruitment in neoplastic tissues and emphasize how tumor-associated macrophages can exert a dual influence in tumor-host interactions.