Immunosuppressive Myeloid Cells in Breast Cancer and Sepsis

Immune cells play paradoxical roles in cancer progression. On one hand, the immune system protects us against tumor development by recognizing and eliminating cancerous cells. On the other hand, tumor-associated immune cells can contribute to tumor progression by secreting growth factors as well as immunosuppressive, pro-angiogenic and/or pro-metastatic mediators. In this thesis we identified a factor (Wnt5a) that may be involved in skewing immune responses towards immunosuppressive, tumor promoting immune cell populations. In a pro-inflammatory setting (i.e. in the presence of exogenous pathogen-associated molecular patterns; PAMPs, or endogenous damage-associated molecular patterns; DAMPs), Wnt5a promoted the generation of immunosuppressive monocytes (CD14+HLA-DRlow/-Co-receptorlow/-). This was at the expense of generation of pro-inflammatory macrophages (M1). In addition, Wnt5a inhibited monocyte to dendritic cell differentiation (Mo-mDC). When co-injecting monocytes from healthy blood donors with MCF-7 or MDA-MB-231 breast cancer cells (luminal A and basal-like, respectively) into immunodeficient mice, monocytes promoted the generation of an activated tumor stroma and were preferentially recruited to basal-like tumors. Furthermore, monocytes from breast cancer patients were affected early during the disease, gradually becoming reprogrammed towards a novel population of monocytic myeloid-derived suppressor cells (Mo-MDSCs). The gene-expression profile of cancer-derived monocytes was remarkably similar to that of reprogrammed immunosuppressive monocytes from patients with gram-negative sepsis. This suggests that Mo-MDSCs may be generated in a similar manner in cancer and sepsis (by reprogramming of monocytes towards an immunosuppressive phenotype). We finally propose that Mo-MDSCs and granulocytic MDSCs are preferentially induced by different PAMPs. Altogether, we conclude that myeloid cells are skewed towards an immunosuppressive and tissue remodeling phenotype early during breast cancer. This resembles the situation during severe infections such as sepsis and most likely has a positive impact on tumor progression

The Generation and Identity of Human Myeloid-Derived Suppressor Cells

Myeloid-derived suppressor cells (MDSCs) are cells of myeloid lineage with a potent immunosuppressive capacity. They are present in cancer patients as well as in patients with severe inflammatory conditions and infections. MDSCs exist as two main subtypes, the granulocytic (G-MDSCs) and the monocytic (Mo-MDSCs) type, as defined by their surface phenotype and functions. While the functions of MDSCs have been investigated in depth, the origin of human MDSCs is less characterized and even controversial. In this review, we recapitulate theories on how MDSCs are generated in mice, and whether this knowledge is translatable into human MDSC biology, as well as on problems of defining MDSCs by their immature cell surface phenotype in relation to the plasticity of myeloid cells. Finally, the challenge of pharmacological targeting of MDSCs in the future is envisioned

Streptococcus pneumoniae Otitis Media Pathogenesis and How It Informs Our Understanding of Vaccine Strategies.

Purpose of Review This study aimed to review the literature regarding the mechanisms of transition from asymptomatic colonization to induction of otitis media and how the insight into the pathogenesis of otitis media has the potential to help design future otitis media-directed vaccines. Recent Findings Respiratory viruses have long been shown to predispose individuals to bacterial respiratory infections, such as otitis media. Recent information suggests that Streptococcus pneumoniae, which colonize the nasopharynx asymptomatical- ly, can sense potentially “threatening” changes in the nasopha- ryngeal environment caused by virus infection by upregulating specific sets of genes involved in biofilm release, dissemination from the nasopharynx to other sites, and protection against the host immune system. Furthermore, an understanding of the transcriptional and proteomic changes occurring in bacteria dur- ing transition to infection has led to identification of novel vaccine targets that are disease-specific and will not affect asymptomatic colonization. This approach will avoid major changes in the delicate balance of microorganisms in the respi- ratory tract microbiome due to elimination of S. pneumoniae. Summary Our recent findings are reviewed in the context of the current literature on the epidemiology and pathogenesis of otitis media. We also discuss how other otopathogens, such as Haemophilus influenzae and Moraxella catarrhalis, as well as the normal respiratory microbiome, can modulate the ability of pneumococci to cause infection. Furthermore, the unsatis- factory protection offered by the pneumococcal conjugate vaccines is highlighted and we review potential future strate- gies emerging to confer a more specific protection against otitis media

On the origin of myeloid-derived suppressor cells

Myeloid-derived suppressor cells (MDSCs) have a strong immunosuppressive character that allows them to regulate immune responses and hinder overt inflammatory responses. In cancer, this leads to tumor immune evasion and disease progression. MDSCs come in at least two forms: monocytic (Mo-MDSCs) and granulocytic (G-MDSCs). The classical definition of MDSCs as immature myeloid cells blocked from differentiating has been challenged by recent studies suggesting that Mo-MDSCs and G-MDSCs may represent monocytes and granulocytes that have acquired immunosuppressive properties. The molecular mechanism behind their generation and their true origins are now widely debated. In this review we discuss the different proposed mechanisms of the generation of both types of MDSCs, with a special focus on human MDSCs in cancer

In vitro and in vivo biofilm formation by pathogenic streptococci

This manuscript presents novel approaches to grow and evaluate Streptococcal biofilm formation using the human respiratory pathogen Streptococcus pneumoniae (the pneumococcus) as the main model organism on biological surfaces in vitro and in vivo. Most biofilm models are based on growth on abiotic surfaces, which is relevant for many pathogens whose growth on surfaces or medical devices is a major cause of disease transmission and infections, especially in hospital environments. However, most infections with commensal organisms require biofilm formation on biological surfaces in the host at the site of colonization or infection. In vitro model systems incorporating biological components from the host and taking into account the host environment of the infectious site are not well described. In a series of publications, we have shown that S. pneumoniae form complex biofilms in the nasopharynx of mice and have devised methodology to evaluate the biofilm structure and function in this environment. We have also been able to recapitulate this biofilm phenotype in vitro by incorporating crucial factors associated with the host environment. Although the protocols presented in this manuscript are focused on S. pneumoniae, the same methodology can and has been used for other Streptococcal species that form biofilms on mucosal surfaces

HAMLET a human milk protein‐lipid complex induces a pro‐inflammatory phenotype of myeloid cells

HAMLET is a protein-lipid complex with a specific and broad bactericidal and tumoricidal activity, that lacks cytotoxic activity against healthy cells. In this study, we show that HAMLET also has general immune-stimulatory effects on primary human monocyte-derived dendritic cells and macrophages (Mo-DC and Mo-M) and murine RAW264.7 macrophages. HAMLET, but not its components alpha-lactalbumin or oleic acid, induces mature CD14low/- CD83+ Mo-DC and M1-like CD14+ CD86++ Mo-M surface phenotypes. Concomitantly, inflammatory mediators, including IL-2, IL-6, IL-10, IL-12 and MIP-1α, were released in the supernatant of HAMLET-stimulated cells, indicating a mainly pro-inflammatory phenotype. The HAMLET-induced phenotype was mediated by calcium, NFκB and p38 MAPK signaling in Mo-DCs and calcium, NFκB and ERK signaling in Mo-M as inhibitors of these pathways almost completely blocked the induction of mature Mo-DCs and M1-like Mo-M. Compared to unstimulated Mo-DCs, HAMLET-stimulated Mo-DC were more potent in inducing T cell proliferation and HAMLET-stimulated macrophages were more efficient in phagocytosis of Streptococcus pneumoniae in vitro. This indicates a functionally activated phenotype of HAMLET-stimulated DCs and macrophages. Combined, we propose that HAMLET has a two-fold anti-bacterial activity; one inducing direct cytotoxic activity, the other indirectly mediating elimination of bacteria by activation of immune cells of the myeloid lineage. This article is protected by copyright. All rights reserved

HAMLET a human milk protein-lipid complex induces a pro-inflammatory phenotype of myeloid cells

HAMLET is a protein-lipid complex with a specific and broad bactericidal and tumoricidal activity, that lacks cytotoxic activity against healthy cells. In this study, we show that HAMLET also has general immune-stimulatory effects on primary human monocyte-derived dendritic cells and macrophages (Mo-DC and Mo-M) and murine RAW264.7 macrophages. HAMLET, but not its components alpha-lactalbumin or oleic acid, induces mature CD14low/- CD83+ Mo-DC and M1-like CD14+ CD86++ Mo-M surface phenotypes. Concomitantly, inflammatory mediators, including IL-2, IL-6, IL-10, IL-12 and MIP-1α, were released in the supernatant of HAMLET-stimulated cells, indicating a mainly pro-inflammatory phenotype. The HAMLET-induced phenotype was mediated by calcium, NFκB and p38 MAPK signaling in Mo-DCs and calcium, NFκB and ERK signaling in Mo-M as inhibitors of these pathways almost completely blocked the induction of mature Mo-DCs and M1-like Mo-M. Compared to unstimulated Mo-DCs, HAMLET-stimulated Mo-DC were more potent in inducing T cell proliferation and HAMLET-stimulated macrophages were more efficient in phagocytosis of Streptococcus pneumoniae in vitro. This indicates a functionally activated phenotype of HAMLET-stimulated DCs and macrophages. Combined, we propose that HAMLET has a two-fold anti-bacterial activity; one inducing direct cytotoxic activity, the other indirectly mediating elimination of bacteria by activation of immune cells of the myeloid lineage. This article is protected by copyright. All rights reserved

Impact of systemic therapy on circulating leukocyte populations in patients with metastatic breast cancer

Tumors affect the immune system, locally and systemically. The frequencies of specific circulating immune cell populations correlate with disease progression as well as prognosis of the patients. Although largely neglected, conventional antitumoral therapies often possess immunomodulatory properties and affect the levels of specific immune cell populations. Most information, however, derive from animal or in vitro studies. As this could impact prognosis as well as response to therapy, further studies of the effects of treatment on circulating immune cells in patients are warranted. In this pilot study, we evaluated a wide panel of circulating immune cells over time (up to six months) in ten patients with metastatic breast cancer receiving standard antitumoral regimens. Overall, endocrine therapy tends to enrich for natural killer (NK) and natural killer T (NKT) cells in the circulation, whereas both chemotherapy and endocrine therapy reduce the levels of circulating monocytic myeloid-derived suppressor cells (Mo-MDSCs). This indicates that the systemic immunosuppressive profile observed in patients tends to revert over the course of systemic therapy and holds promise for future combination treatment with standard antitumoral agents and immunotherapy