Regulation of dendropoiesis in cancer

Tumor associated regulatory dendritic cells

Immune effector and regulatory cells in the tumor microenvironment are key factors in tumor development and progression as the pathogenesis of cancer vitally depends on the multifaceted interactions between various microenvironmental stimuli provided by tumor-associated immune cells. Immune regulatory cells participate in all stages of cancer development from the induction of genomic instability to the maintenance of intratumoral angiogenesis, proliferation and spreading of malignant cells, and formation of premetastatic niches in distal tissues. Dendritic cells in the tumor microenvironment serve as a double-edged sword and, in addition to initiating potent anti-tumor immune responses, may mediate genomic damage, support neovascularization, block anti-tumor immunity and stimulate cancerous cell growth and spreading. Regulatory dendritic cells in cancer may directly and indirectly maintain antigen-specific and non-specific T cell unresponsiveness by controlling T cell polarization, MDSC and Treg differentiation and activity, and affecting specific microenvironmental conditions in premalignant niches. Understanding the mechanisms involved in regulatory dendritic cell polarization and operation and revealing pharmacological means for harnessing these pathways will provide additional opportunities for modifying the tumor microenvironment and improving the efficacy of different therapeutic approaches to cancer.

Intratumoral cytokines/chemokines/growth factors and tumor infiltrating dendritic cells: friends or enemies?

The tumor microenvironment consists of a variable combination of tumor cells, stromal fibroblasts, endothelial cells and infiltrating leukocytes, such as macrophages, T lymphocytes, and dendritic cells. A variety of cytokines, chemokines and growth factors are produced in the local tumor environment by different cells accounting for a complex cell interaction and regulation of differentiation, activation, function and survival of multiple cell types. The interaction between cytokines, chemokines, growth factors and their receptors forms a comprehensive network at the tumor site, which is primary responsible for overall tumor progression and spreading or induction of antitumor immune responses and tumor rejection. Although the general thought is that dendritic cells are among the first cells migrating to the tumor site and recognizing tumor cells for the induction of specific antitumor immunity, the clinical relevance of dendritic cells at the site of the tumor remains a matter of debate regarding their role in the generation of successful antitumor immune responses in human cancers. While several lines of evidence suggest that intratumoral dendritic cells play an important role in antitumor immune responses, understanding the mechanisms of dendritic cell/tumor cell interaction and modulation of activity and function of different dendritic cell subtypes at the tumor site is incomplete. This review is limited to discussing the role of intratumoral cytokine network in the understanding immunobiology of tumor-associated dendritic cells, which seems to possess different regulatory functions at the tumor site.

TNF-alpha protects dendritic cells from prostate cancer-induced apoptosis

We have recently shown that human prostate cancer (PCa) cells induced apoptotic death of the most potent antigen-presenting cells, dendritic cells (DC), which are responsible for the induction of specific antitumor immune responses. Here we have evaluated the effect of murine PCa cells RM-1 on the survival of immature and tumor necrosis factor-alpha (TNF-alpha)-stimulated mature DC. PCa cells and DC were co-incubated for 24-48 h and DC apoptosis was assessed by morphologic criteria, Annexin V assay, and TUNEL staining. We have shown that co-incubation of RM-1 cells with DC is accompanied by an increased level of DC apoptosis, which was mediated by decreased expression of anti-apoptotic protein Bcl-2. Stimulation of DC maturation by TNF-alpha resulted in increased resistance of DC to PCa-induced apoptosis. In TNF-alpha treated mature DC, but not in immature DC, the expression of Bcl-2 was not blocked after exposure to RM-1-derived factors. Thus, these data suggest that TNF-alpha-induced maturation of DC increases their resistance to PCa induced apoptosis. This is likely to be due to the stabilizing of the expression of anti-apoptotic protein Bcl-2. The difference in the sensitivity of mature and immature DC to PCa-induced cell death should be considered during the design of DC-based clinical trials for PCa patients.Prostate Cancer and Prostatic Diseases (2001) 4, 221-227.

Inhibition of CD40 expression and CD40-mediated dendritic cell function by tumor-derived IL-10

As CD40 plays a key role in both antitumor immunity and DC maturation, we have studied the regulation of its expression during DC hematopoiesis (dendropoiesis) in vitro and in vivo in the tumor microenvironment. Using MC38 colon adenocarcinoma tumor models, we have demonstrated that DCs generated in vitro from bone marrow precursors obtained from tumor-bearers have significantly lower expression of CD40 molecules compared to DCs generated from tumor-free mice. Furthermore, CD40 expression on DCs isolated from the spleens of tumor-bearing mice was also significantly reduced, suggesting that tumor-derived factors inhibit CD40 expression on DCs during dendropoiesis both in vitro and in vivo. Interestingly, CD40 ligation on DCs generated from tumor-bearers did not result in inducible expression of IL-12 protein or IL-12 p40 mRNA. However, Staphylococcus aureus-induced IL-12 production by DCs was not altered in tumor-bearers, confirming that inhibition of IL-12 production by DCs generated in vitro from tumor-bearing mice was due to reduced expression of CD40 on DCs. We have also shown that MC38 tumor cells produce IL-10 and that exogenous IL-10 causes downregulation of CD40 expression on DCs. In addition, endogenous IL-10 produced by colon carcinoma cells inhibited CD40-dependent IL-12 production by DCs since tumor-induced inhibition of IL-12 production was abrogated by neutralizing anti-IL-10 antibody. Finally, systemic administration of FLT3L and/or CD40L reversed CD40 and IL-12 (p40) deficiency of DCs in tumor-bearing mice in vivo. These findings thus demonstrate that tumor-derived factors, including IL-10, inhibit CD40 expression on DCs and DC precursors and suppress their maturation and function.

Human prostate cancer regulates generation and maturation of monocyte-derived dendritic cells

BACKGROUND

The progression of prostate cancer is accompanied by a marked suppression of the immune system, including the apoptotic death of dendritic cells (DC) responsible for the induction of antitumor immunity. In this study, we evaluated whether prostate cancer might inhibit DC generation and maturation in vitro.

METHODS

DC were generated from peripheral blood monocytes in the presence of the human prostate cell line LNCaP or nonmalignant cells, and characterized by light microscopy, FACScan analysis, and ability to stimulate T-cell proliferation.

RESULTS

Prostate cancer significantly inhibited the conversion of monocytes into DC, which was assessed by the expression of DC markers CD1a and CD83. These cells were weak stimulators of T-cell proliferation, suggesting that DC generated in the prostate cancer microenvironment are functionally inhibited.

CONCLUSIONS

Prostate cancer not only kills mature DC, but also inhibits their generation and maturation, resulting in decreased production of antigen-presenting cells and inhibition of their functional activity.

Human small cell lung carcinoma and carcinoid tumor regulate dendritic cell maturation and function

The induction of apoptosis in dendritic cells (DC) is a key mechanism by which tumors escape immune recognition and elimination. In fact, a number of studies have showed the correlation between the number of DC within the tumor and the clinical prognosis, suggesting that increased infiltration of tumor tissue by DC was associated with better patient survival and low incidence of metastatic disease. We compared the number of DC and their distribution pattern in human small-cell lung carcinoma and bronchial carcinoid tumor (CT) tissues. Immunohistochemical analysis revealed the presence of cells expressing DC markers CD1a and CD83 in small-cell lung carcinoma tissues and the complete absence of these cells in CT samples. Next, we examined whether human lung tumor cells produce soluble factors that inhibit differentiation of hematopoietic precursors into mature DC. The addition of small-cell lung carcinoma-conditioned medium to CD34+ precursor cell cultures significantly inhibited colony-forming units of DC formation when compared with nontreated control DC cultures. Furthermore, DC generation and differentiation was completely abrogated in CD34+ cell cultures treated with CT-conditioned medium, suggesting that CT-derived factors blocked CD34+ cell differentiation into DC or induced their apoptosis. Finally, flow cytometry analysis of cultured DC confirmed these results. Thus, analysis of our data suggests that human lung tumors produce factors that inhibit DC generation or maturation and may also induce apoptotic death of DC precursors in vitro.