Francesca Mion

Mast Cells Boost Myeloid-Derived Suppressor Cell Activity and Contribute to the Development of Tumor-Favoring Microenvironment

Danelli and colleagues demonstrate interactions between mast cells and myeloid-derived suppressor cells in the mucosa of colon carcinoma patients and in the colon and spleen of tumor-bearing mice and establish the role of CD40/CD40L in the activity of these cells in colon cancer. Inflammation plays crucial roles at different stages of tumor development and may lead to the failure of immune surveillance and immunotherapy. Myeloid-derived suppressor cells (MDSC) are one of the major components of the immune-suppressive network that favors tumor growth, and their interaction with mast cells is emerging as critical for the outcome of the tumor-associated immune response. Herein, we showed the occurrence of cell-to-cell interactions between MDSCs and mast cells in the mucosa of patients with colon carcinoma and in the colon and spleen of tumor-bearing mice. Furthermore, we demonstrated that the CT-26 colon cancer cells induced the accumulation of CD11b+Gr1+ immature MDSCs and the recruitment of protumoral mast cells at the tumor site. Using ex vivo analyses, we showed that mast cells have the ability to increase the suppressive properties of spleen-derived monocytic MDSCs, through a mechanism involving IFNγ and nitric oxide production. In addition, we demonstrated that the CD40:CD40L cross-talk between the two cell populations is responsible for the instauration of a proinflammatory microenvironment and for the increase in the production of mediators that can further support MDSC mobilization and tumor growth. In light of these results, interfering with the MDSC:mast cell axis could be a promising approach to abrogate MDSC-related immune suppression and to improve the antitumor immune response. Cancer Immunol Res; 3(1); 85–95. ©2014 AACR.

Mast Cell: An Emerging Partner in Immune Interaction

Mast cells (MCs) are currently recognized as effector cells in many settings of the immune response, including host defense, immune regulation, allergy, chronic inflammation, and autoimmune diseases. MC pleiotropic functions reflect their ability to secrete a wide spectrum of preformed or newly synthesized biologically active products with pro-inflammatory, anti-inflammatory and/or immunosuppressive properties, in response to multiple signals. Moreover, the modulation of MC effector phenotypes relies on the interaction of a wide variety of membrane molecules involved in cell–cell or cell-extracellular-matrix interaction. The delivery of co-stimulatory signals allows MC to specifically communicate with immune cells belonging to both innate and acquired immunity, as well as with non-immune tissue-specific cell types. This article reviews and discusses the evidence that MC membrane-expressed molecules play a central role in regulating MC priming and activation and in the modulation of innate and adaptive immune response not only against host injury, but also in peripheral tolerance and tumor-surveillance or -escape. The complex expression of MC surface molecules may be regarded as a measure of connectivity, with altered patterns of cell–cell interaction representing functionally distinct MC states. We will focalize our attention on roles and functions of recently discovered molecules involved in the cross-talk of MCs with other immune partners.

Mast cells, basophils and B cell connection network.

It has been proven that both resting and activated mast cells (MCs) and basophils are able to induce a significant increase in proliferation and survival of naïve and activated B cells, and their differentiation into antibody-producing cells. The immunological context in which this regulation occurs is of particular interest and the idea that these innate cells induce antibody class switching and production is increasingly gaining ground. This direct role of MCs and basophils in acquired immunity requires cell to cell contact as well as soluble factors and exosomes. Here, we review our current understanding of the interaction between B cells and MCs or basophils as well as the evidence supporting B lymphocyte-MC/basophil crosstalk in pathological settings. Furthermore, we underline the obscure aspects of this interaction that could serve as important starting points for future research in the field of MC and basophil biology in the peculiar context of the connection between innate and adaptive immunity.

IL-10 production by B cells is differentially regulated by immune-mediated and infectious stimuli and requires p38 activation.

IL-10 is an immune suppressive cytokine with pleiotropic effects on B cell biology. IL-10 production has a pivotal role for the regulatory suppressive functions that B cells exert in many physiological and pathological settings. Several exogenous stimuli and endogenous immune mediators can trigger IL-10-producing B cell maturation. To clarify and gain a better insight into the mechanisms of IL-10 production by B cells, we first compared the effects of LPS, CpG, agonistic CD40 mAb and BAFF on IL-10 production, and then we investigated the signal transduction mechanisms responsible for these responses. While infectious/danger stimuli determine the rapid production and release of IL-10 by B cells, a limited subset of CD40-poised, IL-10-competent B cells produce IL-10 in response to a later antigenic or infectious signal. Although BAFF is able to induce a similar subset of IL-10-competent B cells, these cells do not similarly respond to the same antigenic or infectious signals. Importantly, by using specific inhibitors of the MAP kinase pathways, we found that while il-10 gene expression triggered by the TLR agonists LPS and CpG is strongly dependent on p38 activity, the induction of IL-10 competence in CD40-activated B cells does not depend on ERK1/2, p38 or JNK pathways.

Mast Cells Control the Expansion and Differentiation of IL-10–Competent B Cells

The discovery of B cell subsets with regulatory properties, dependent on IL-10 production, has expanded our view on the mechanisms that control inflammation. Regulatory B cells acquire the ability to produce IL-10 in a stepwise process: first, they become IL-10 competent, a poised state in which B cells are sensitive to trigger signals but do not actually express the Il-10 gene; then, when exposed to appropriate stimuli, they start producing IL-10. Even if the existence of IL-10–competent B cells is now well established, it is not yet known how different immune cell types cross talk with B cells and affect IL-10–competent B cell differentiation and expansion. Mast cells (MCs) contribute to the differentiation and influence the effector functions of various immune cells, including B lymphocytes. In this study, we explored whether MCs could play a role in the expansion of IL-10–competent B cells and addressed the in vivo relevance of MC deficiency on the generation of these cells. We show that MCs can expand IL-10–competent B cells, but they do not directly induce IL-10 production; moreover, the absence of MCs negatively affects IL-10–competent B cell differentiation. Noteworthy, our findings reveal that the CD40L/CD40 axis plays a significant role in MC-driven expansion of IL-10–competent B cells in vitro and highlight the importance of MC CD40L signaling in the colon.

Is it time for a new classification of mast cells? What do we know about mast cell heterogeneity?

Mast cells (MCs) are derived from committed precursors that leave the hematopoietic tissue, migrate in the blood, and colonize peripheral tissues where they terminally differentiate under microenvironment stimuli. They are distributed in almost all vascularized tissues where they act both as immune effectors and housekeeping cells, contributing to tissue homeostasis. Historically, MCs were classified into 2 subtypes, according to tryptic enzymes expression. However, MCs display a striking heterogeneity that reflects a complex interplay between different microenvironmental signals delivered by various tissues, and a differentiation program that decides their identity. Moreover, tissue‐specific MCs show a trained memory, which contributes to shape their function in a specific microenvironment. In this review, we summarize the current state of our understanding of MC heterogeneity that reflects their different tissue experiences. We describe the discovery of unique cell molecules that can be used to distinguish specific MC subsets in vivo, and discuss how the improved ability to recognize these subsets provided new insights into the biology of MCs. These recent advances will be helpful for the understanding of the specific role of individual MC subsets in the control of tissue homeostasis, and in the regulation of pathological conditions such as infection, autoimmunity, and cancer.

Message in a bottle from the tumor microenvironment: tumor-educated DCs instruct B cells to participate in immunosuppression

Once tumour cells have overcome the molecular mechanisms that prevent their uncontrolled proliferation, the only enemy they need to deal with is the immune system, which is able to recognize and destroy transformed cells. Paradoxically, one of the evasion mechanisms put in place by the tumour is made by the suppressive arm of the immune system itself, which has therefore the double capacity of promoting and suppressing cancer cell growth and dissemination. B lymphocytes reflect this duality of the immune system.

Reciprocal influence of B cells and tumor macro and microenvironments in the ApcMin/+ model of colorectal cancer

ABSTRACT One of the most fascinating aspects of the immune system is its dynamism, meant as the ability to change and readapt according to the organism needs. Following an insult, we assist to the spontaneous organization of different immune cells which cooperate, locally and at distance, to build up an appropriate response. Throughout tumor progression, adaptations within the systemic tumor environment, or macroenvironment, result in the promotion of tumor growth, tumor invasion and metastasis to distal organs, but also to dramatic changes in the activity and composition of the immune system. In this work, we show the changes of the B-cell arm of the immune system following tumor progression in the ApcMin/+ model of colorectal cancer. Tumor macroenvironment leads to an increased proportion of total and IL-10-competent B cells in draining LNs while activates a differentiation route that leads to the expansion of IgA+ lymphocytes in the spleen and peritoneum. Importantly, serum IgA levels were significantly higher in ApcMin/+ than Wt mice. The peculiar involvement of IgA response in the adenomatous transformation had correlates in the gut-mucosal compartment where IgA-positive elements increased from normal mucosa to areas of low grade dysplasia while decreasing upon overt carcinomatous transformation. Altogether, our findings provide a snapshot of the tumor education of B lymphocytes in the ApcMin/+ model of colorectal cancer. Understanding how tumor macroenvironment affects the differentiation, function and distribution of B lymphocytes is pivotal to the generation of specific therapies, targeted to switching B cells to an anti-, rather than pro-, tumoral phenotype.

Deciphering new mechanisms on T‐cell costimulation by human mast cells

It is well established that full activation of T cells to recognize a specific antigen requires additional signals. These secondary signals are generated by the interaction of costimulatory molecules expressed on APCs. Classical APCs include DCs, macrophages, Langerhans cells, and B cells. However, in recent years, several haematopoietic and nonhaematopoietic cells have been described to express MHC class II antigens and, in appropriate conditions, costimulatory molecules. In this issue, Suurmond et al. [Eur. J. Immunol. 2016. 46: 1132–1141] show, for the first time, that human mast cells not only express costimulatory molecules of the TNF‐receptor and CD28 families, but can also costimulate T cells through a yet‐to‐be‐defined CD28‐independent interaction.

Use of cocultures for the study of cellular interactions influencing B cell regulatory functions.

Many immunological processes are contextually controlled by complex interactions among different cell types. Several studies have shown that B cells produce the immune regulatory cytokine IL-10 in response to different external stimuli but also to immune-mediated signals. Endogenous signals that derive from the cross talk between B lymphocytes and other cells of the immune system can affect IL-10 production by B cells in both physiological and pathological conditions. With the aim to provide a guide for the study of how partner cells can induce IL-10-producing B cells, here we describe the protocols to investigate IL-10 production at a single cell level in a dendritic cell-B cell coculture in vitro system. These methods are a proof of concept that can be easily extrapolated and adapted to the study of the interaction between B cells and other immune cell types.