Microvesicles secreted by macrophages shuttle invasion-potentiating microRNAs into breast cancer cells

Recent advances on the role of tumor exosomes in immunosuppression and disease progression

Exosomes are endosomal-derived nanovesicles released by most cells types, including tumor cells, and principally involved in intercellular communication in physiology and disease. Tumor exosomes are gaining increasing interest in medicine and oncology as efficient tools for the delivery of defined signals. Representing the acellular replicas of tumor cells, they contain a great variety of bioactive molecules, such as proteins, RNA, miRNA and DNA. Their great ability to recirculate in body fluids and their structure allow them to transport their cargo to distant targets. Major studies have shown that tumor exosomes convey information not only between tumor cells but also to other cell types, including different immune cell components. There is increasing evidence that these nanovesicles may contribute to cancer progression by influencing different immune cell types, likely blunting specific T cell immunity and skewing innate immune cells toward a pro-tumorigenic phenotype. Because of this function and the additional property to deliver molecular signals modulating neoangiogenesis and stroma remodeling, tumor exosomes are believed to play a role in tumor progression by favoring metastatic niche onset. This review outlines the recent knowledge on immune suppressive mechanisms mediated by tumor exosomes. We will discuss our view on the role of these nanovesicular structures in cancer progression and how their presence could interfere with cancer therapy.

miR-511-3p modulates genetic programs of tumor-associated macrophages

Expression of the mannose receptor (MRC1/CD206) identifies macrophage subtypes, such as alternatively activated macrophages (AAMs) and M2-polarized tumor-associated macrophages (TAMs), which are endowed with tissue-remodeling, proangiogenic, and protumoral activity. However, the significance of MRC1 expression for TAM's protumoral activity is unclear. Here, we describe and characterize miR-511-3p, an intronic microRNA (miRNA) encoded by both mouse and human MRC1 genes. By using sensitive miRNA reporter vectors, we demonstrate robust expression and bioactivity of miR-511-3p in MRC1(+) AAMs and TAMs. Unexpectedly, enforced expression of miR-511-3p tuned down the protumoral gene signature of MRC1(+) TAMs and inhibited tumor growth. Our findings suggest that transcriptional activation of Mrc1 in TAMs evokes a genetic program orchestrated by miR-511-3p, which limits rather than enhances their protumoral functions. Besides uncovering a role for MRC1 as gatekeeper of TAM's protumoral genetic programs, these observations suggest that endogenous miRNAs may operate to establish thresholds for inflammatory cell activation in tumors.

Conjunction of tumor cells with lymphocytes: implications for tumor invasion and metastasis

Our previous studies have led to a novel hypothesis that tumor metastasis is triggered by aberrant lymphocyte infiltration that disrupts intercellular junctions and surface adhesion molecules and causes dissociation of tumor cells from the primary tumor core, allowing lymphocytes to conjoin with dissociated tumor cells and physically 'drag' them to different tissue sites. Our hypothesis is supported by morphological and immunohistochemical data from multiple types of human cancer. This hypothesis challenges the traditional belief that the physical conjunction between tumor cells and lymphocytes would lead to degeneration of the tumor cells. To validate our hypothesis, H&E and immunostained sections were examined under high magnification to identify potential signs of degeneration-related changes. Our study revealed that >60% of isolated tumor cells overlying focal capsule disruptions, or within the stroma and vascular structures, were physically conjoined with lymphocytes to form tumor cell-lymphocyte chimeras (TLCs). Approximately 90% of the tumor cell partners of TLCs were morphologically indistinguishable from their counterparts within the tumor core. In addition, one third of the tumor cells of TLCs expressed high levels of cell proliferation specific proteins, or were undergoing mitosis. Our study also revealed that a subset of dilated lymphatic ducts or blood vessels at the site of focal capsule disruptions harbored variable numbers of tumor cells, and the wall of these structures was in direct physical continuity with the myoepithelial cell layer. Our study suggests that the onset of tumor metastasis may occur in two forms: (1) lymphocyte-mediated shuttling that allows lymphocytes to physically 'drag' tumor cells to different sites, and (2) tumor progenitor-mediated angiogenesis that allows tumor cells to directly enter the vascular structures.

Non-coding RNAs in cancer initiation and progression and as novel biomarkers

Cancer represents a complex group of heterogeneous diseases. While many cancers share fundamental biological processes (hallmarks of cancer) necessary for their development and progression, cancers also distinguish themselves by their dependence on distinct oncogenic pathways. Over the last decade, targeted therapies have been introduced to the clinic with variable success. In truth, single targeted therapies may be successful in only a subset of malignancies but insufficient to address malignancies that often rely on multiple pathways, thus evading single targeted agents. Investigators have recently identified potentially functional components of the human genome that were previously thought to have no biological function. This discovery has added to the already established complexity of gene regulation in the pathogenesis of cancer. Non-coding RNAs represent key regulators of gene expression. Improved knowledge of their biogenesis and function may in turn lead to a better understanding of the heterogeneity of malignancies and eventually be leveraged as diagnostic, prognostic and therapeutic targets. MicroRNAs (miRNAs or miRs) for example, have the capacity for the regulation of multiple genes and thus redirection or reprogramming of biological pathways. However, several other members of the non-coding RNA family may be of equal biological relevance. In this review, we provide a perspective on emerging concepts in the clinical application of miRNA and other non-coding RNAs as biomarkers in cancer with an eye on the eventual integration of both miRNA and other non-coding RNA biology into our understanding of cancer pathogenesis and treatment.

miRNA-mediated immune regulation and immunotherapeutic potential in glioblastoma

Glioblastoma (GB), the most common primary neoplasm of the CNS, remains universally fatal with standard therapies and has a mean overall survival time of only 14.6 months. Even in the most favorable situations most patients do not survive longer than 2 years. Another hallmark of GBs, apart from the poor control of proliferation, is an immune suppressed tumor microenvironment. miRNAs usually bind the 3' untranslated region of target mRNAs and direct their post-transcriptional repression. Certain miRNAs are known to have altered expression levels in GB tumors, and in many immune cell subtypes. miRNAs have been found to serve important roles in gene regulation and are implicated in many processes in oncogenesis and immune deregulation. In this article we focus on the miRNAs involved in gliomagenesis and in the regulation of the immune response. We also present current challenges and miRNA immunotherapeutic strategies that should be investigated further.