Signaling by exosomal microRNAs in cancer

The first observations that mature miRNAs are present in cell-free blood plasma and serum was made in 2008 by several independent research groups [5-8]. Later, nuclease resistant extracellular miRNAs have been found in all known biological fluids [9-12]. Since then, accumulated reports have consistently shown that extracellular miRNAs can be shielded from RNAse degradation by: (1) packaging in microvesicles (MVs) such as apoptotic bodies, shedding vesicles and exosomes; or (2) solely by complexing with AGO proteins [13-15]. Most miRNAs present in biological fluid have been found MVs-free and associated with proteins of the Ago family, which appear remarkably stable even in protease rich environment [16,17]. Some miRNA species were also found in purified fractions of high-density lipoprotein (HDL) from human plasma [18,19], although the analyzed HDL-miRNAs constituted only a minor proportion of the total circulating miRNAs. Circulating miRNAs bound by Ago proteins are apparently non-specific remnants resulting from physiological activity of the cells and cell death [15,17]. On the contrary, extracellular miRNAs included within MVs can be transferred to recipient cells, alter gene expression and mediate functional effects [20-25].

Exosomes have been found to act as vehicles for suppressive signals and have suppressive effects on antitumor immune responses [35,69]. For instance, miR-9 that is over-expressed in many cancers is able of inhibiting the transcription of the MHC class I gene thus preventing the recognition of tumor cells by the patient immune system [70]. Yet, miR-222 down-regulates the expression on tumor cell surfaces of intracellular cell adhesion molecule 1 (ICAM-1) whose binding to lymphocyte function-associated antigen (LFA-1) is essential for optimal activation of cytotoxic T cells, which in turn mediate tumor cell lysis [71].

In some cases, exosomal pathways might discard tumor-suppressor miRNAs that restrict metastatic progression. For example, the let-7 miRNA family was shown to be expressed at higher levels in exosomes derived from metastatic gastric cancer cells, compared to non-metastatic parental cells, suggesting that the exosomal mechanism may be used by metastatic cells to eliminate miRNAs having tumor suppressive functions, thus strengthening their aggressive behavior [72]. Another example comes from a recent paper showing that metastatic cells from bladder carcinoma secrete increased levels of miRNAs with tumor-suppressor functions (e.g. inhibition of invasion, angiogenesis, and pulmonary metastasis), including miR-23b, miR-224, and miR-921. Moreover, miRNAs, such as miR-23b, highly exocytosed from metastatic cells were reduced in lymph node metastases compared with patient-matched primary tumors [73]. These results suggest that exosome-mediated secretion of tumor-suppressor miRNAs is selected during tumor progression as a mechanism to coordinate activation of a metastatic cascade. An alternative hypothesis has been proposed to justify the relative abundance of miRNAs with predominant tumor suppressor activity in the blood of healthy individuals. According to this hypothesis, tumor-suppressor circulating miRNAs might work as a surveillance mechanism exerting continuous inhibition on tumor formation, complementing cancer immune surveillance [74]. It should be noted, however, that, in other instances, miR-23b may act as tumor promoting [75].

However, most literature reports a tumor promoting role of exosomal miRNAs, likely because tumor suppressor miRNAs are downregulated in many tumors, as well as in cancer stem cells. Many oncomiRs have been described in the past decade. For example, IL-4 activated macrophages have been shown to regulate invasiveness of breast cancer cells through exosome-mediated delivery of the miR-223 highlighting a novel communication mechanism between tumor-associated macrophages and cancer cells [76]. miR-21 has been found up-regulated in a wide range of solid tumors [77,78], and secreted in plasma exosomes from patients affected by different cancer types, such as ovarian, lung and colon carcinomas, pancreatic cancer and others, its presence being always positively correlated with tumor progression and aggressiveness [79-82]. Up-regulation of miR-21 was shown to promote cellular proliferation, survival, invasion and migration in different cancer cell lines [83], while its knock-down decreased tumor cell survival in vitro and tumor growth in vivo in a murine xenograft model, accompanied by enhanced apoptosis [84]. Interestingly, miR-21 and -29a secreted by tumor cells via exosomes have been shown to bind to toll-like receptors (TRL) on immune cells, leading to TLR-mediated NF-κB (nuclear factor kappa-light-chain-enhancer of activated B cells) activation and secretion of prometastatic inflammatory cytokines that may ultimately lead to tumor growth and metastasis [85].

It is becoming clear that tumor released exosomes contribute to both progression of primary tumors and metastases. The central role of exosomes in tumor promotion has been recently highlighted by the discovery that breast cancer exosomes can perform cell-independent miRNA biogenesis and stimulate non-tumorigenic epithelial cells to form tumors, by altering their transcriptome in a Dicer-dependent manner [56]. The metastatic process involves the manipulation of the cellular microenvironment to optimize conditions for deposition and growth both locally and at a distance for tumor colonization [86,87].

It was recently reported that melanoma exosomes can modify distant lymph nodes to facilitate melanoma growth and metastasis even in the local absence of tumor cells [88]. Exosomal miRNAs derived from metastatic adenocarcinoma cells were also involved in modulation of premetastatic organ stroma cells toward supporting tumor cell hosting. Exosomal mRNAs and miRNAs derived from tumor cells were recovered in lymph node stroma and lung fibroblasts, and were shown to significantly affect mRNA translation in the target cells, exemplified by abundant recovery of exosomal miR-494 and miR-542-3p, which targeted cadherin17 [89]. In addition to modulation of stromal cells, recent data have also demonstrated a pivotal role for cancer cell–derived exosomes in the organization of the extracellular matrix (ECM). Being rich in proteases, exosomes can modulate the ECM for degradation of collagens, laminin, and fibronectin, and this may have severe consequences on tumor and host cell adhesion, motility, and invasiveness [90].

Exosomal miRNAs can also participate in cancer metastasis by adapting the tumor niche cells. miR-105, which is characteristically expressed and secreted by metastatic breast cancer cells, is a potent regulator of migration through targeting the tight junction protein ZO-1. In endothelial monolayers, exosome-mediated transfer of cancer-secreted miR-105 efficiently destroys tight junctions and the integrity of these natural barriers against metastasis. Overexpression of miR-105 in non-metastatic cancer cells induces metastasis and vascular permeability in distant organs, whereas inhibition of miR-105 in highly metastatic tumors alleviates these effects [91]. It has been recently shown that miR-200 family members, which regulates the mesenchymal-to-epithelial transition, within extracellular vesicles secreted from highly metastatic tumor cells can be internalized by weakly metastatic cells and confer the capability of tumor growth at metastatic lesions [92,93].

The contribution of exosome in induction of angiogenesis to promote cancer metastasis is also described. For instance, it was shown that miRNA-enriched exosomes released by CD105 cancer stem cells from renal carcinomas may modify the tumor microenvironment by triggering angiogenesis and may promote formation of a pre-metastatic niche [42]. Specific exosomal miRNAs, such as those of the miR-17-92 cluster, have an important role in neoplasia-to-endothelial cell communication for regulating endothelial gene expression during tumor angiogenesis in leukemia cells [94]. It was also shown that tumor-secreted miR-9 encapsulated into microvesicles promotes endothelial cell migration and tumour angiogenesis participating in intercellular communication and function [95]. Moreover, exosomal angiogenic miR-210, known to be increased in the serum of cancer patients with malignant breast cancer, regulate the metastatic ability of cancer cells through suppression of specific target genes, which resulted in enhanced angiogenesis [96]. In addition, neutral sphyngomyelinase 2 (nSMase2) was required to regulate exosomal miRNA secretion from cancer cells and promote angiogenesis within the tumor microenvironment as well as metastasis [96]. These findings suggest that the horizontal transfer of exosomal miRNAs from cancer cells can dictate the microenviromental niche for the benefit of cancer progression. Some studies also suggest that the microenvironment may play a crucial role in regulating the pathogenesis of some tumors by modulating the expression of exosomal miRNAs. Bone marrow stromal cells modulate miR-15a, which act as putative tumor suppressor in multiple myeloma cells thus facilitating the progression of this tumor [97-100].

The exosomal miRNA profiling of sera from cancer patients versus healthy individuals has often revealed important differences in relation to tumor progression, highlighting a possible use of these miRNAs as disease prognostic biomarkers [101,102]. In addition, many tumors displaying drug resistance show alterations in the expression of miRNAs. The up- or down-regulation of miRNAs affects the expression of several target proteins (drug targets, transporters, cell cycle- and apoptosis-related components, key signaling pathway components involved in drug response), determining changes in drug sensitivity through different molecular mechanisms [103,104]. Moreover, different studies indicate that exosomes act as vehicles for exchange of genetic cargo between heterogeneous populations of tumor cells, generating a way of transmitting drug resistance [105-107]. Recently Chen and colleagues reported that exosomes from drug resistant breast cancer cells are capable of delivering a subset of miRNAs (miR-100, miR-222 and miR-30a) to sensitive cells [108]. miR-34a, detected as both intracellular and exosomal biomarker, was recently found also to influence prostate cancer cell response to docetaxel by regulating anti-apoptotic BCL-2 gene [109]. In addition, the inhibition of miR-9 expression in chemoresistant glioblastoma multiforme (GBM) cells, by transferring to GBM cells miR-9 microvesicles-encapsulated inhibitors, resulted in reversed expression of the multidrug transporter and sensitized GBM cells to the treatments [110].