Confocal microscopy analysis reveals that only a small proportion of extracellular vesicles are successfully labelled with commonly utilised staining methods.

Assessing genuine extracellular vesicle (EV) uptake is crucial for understanding the functional roles of EVs. This study measured the bona fide labelling of EVs utilising two commonly used fluorescent dyes, PKH26 and C5-maleimide-Alexa633. MCF7 EVs tagged with mEmerald-CD81 were isolated from conditioned media by size exclusion chromatography (SEC) and characterised using Nanoparticle Tracking Analysis (NTA), Transmission Electron Microscopy (TEM), MACsPlex immunocapture assay and immunoblots. These fluorescently tagged EVs were subsequently stained with C5-maleimide-Alexa633 or PKH26, according to published protocols. Colocalisation of dual-labelled EVs was assessed by confocal microscopy and quantified using the Rank-Weighted Colocalisation (RWC) algorithm. We observed strikingly poor colocalisation between mEmerald-CD81-tagged EVs and C5-Maleimide-Alexa633 (5.4% ± 1.8) or PKH26 (4.6% ± 1.6), that remained low even when serum was removed from preparations. Our data confirms previous work showing that some dyes form contaminating aggregates. Furthermore, uptake studies showed that maleimide and mEmerald-CD81-tagged EVs can be often located into non-overlapping subcellular locations. By using common methods to isolate and stain EVs we observed that most EVs remained unstained and most dye signal does not appear to be EV associated. Our work shows that there is an urgent need for optimisation and standardisation in how EV researchers use these tools to assess genuine EV signals.

Extracellular Vesicles: Emerging Modulators of Cancer Drug Resistance.

Extracellular vesicles (EVs) have recently emerged as crucial modulators of cancer drug resistance. Indeed, it has been shown that they can directly sequester anti-tumor drugs, decreasing their effective concentration at target sites. Moreover, they facilitate the horizontal transfer of specific bioactive cargoes able to regulate proliferative, apoptotic, and stemness programs in recipient cells, potentially conferring a resistant phenotype to drug-sensitive cancer cells. Finally, EVs can mediate the communication between the tumor and both stromal and immune cells within the microenvironment, promoting treatment escape. In this context, clarifying the EV-driven resistance mechanisms might improve not only tumor diagnosis and prognosis but also therapeutic outcomes. Detailed cellular and molecular events occurring during the development of EV-mediated cancer drug resistance are described in this review article.

The Challenges and Possibilities of Extracellular Vesicles as Therapeutic Vehicles.

Extracellular vesicles (EVs) are small lipid-enclosed particles that can carry various types of cargo, including proteins, nucleic acids and metabolites. They are known to be released by all cell types and can be taken up by other cells, leading to the transfer of the cargo they carry. As such, they represent an important type of intercellular signalling and a natural mechanism for transferring macromolecules between cells. This ability to transfer cargo could be harnessed to deliver therapeutic molecules. Indeed, a growing body of work has described the attempt by the field to utilise EVs to deliver a range of therapeutics including RNAi, CRISPR/Cas9 and chemotherapeutics, to a specific target tissue. However, there are numerous barriers associated with the use of EVs as therapeutic vehicles, including the challenge of efficiently loading therapeutics into EVs, avoiding clearance of the EVs from circulation, targeting the correct tissue type and the inefficiency of internalisation and functional delivery of the cargo. Despite these difficulties, EVs represent a tremendous therapeutic opportunity, both for the delivery of exogenous cargo, as well as the therapeutic benefit of targeting aberrant EV signalling or treating patients with natural EVs, such as those released by mesenchymal stem cells. This review describes current knowledge on the therapeutic potential of EVs and the challenges faced by the field. Many of these challenges are due to a lack of complete understanding of EV function, but further research in this area should continue to yield new solutions that will lead to the use of EVs in the clinic.

A miRNA-145/TGF-ß1 negative feedback loop regulates the cancer-associated fibroblast phenotype.

The dissemination of cancer cells to local and distant sites depends on a complex and poorly understood interplay between malignant cells and the cellular and non-cellular components surrounding them, collectively termed the tumour microenvironment. One of the most abundant cell types of the tumour microenvironment is the fibroblast, which becomes corrupted by locally derived cues such as TGF-ß1 and acquires an altered, heterogeneous phenotype (cancer-associated fibroblasts, CAF) supportive of tumour cell invasion and metastasis. Efforts to develop new treatments targeting the tumour mesenchyme are hampered by a poor understanding of the mechanisms underlying the development of CAF. Here, we examine the contribution of microRNA to the development of experimentally-derived CAF and correlate this with changes observed in CAF derived from tumours. Exposure of primary normal human fibroblasts to TGF-ß1 resulted in the acquisition of a myofibroblastic CAF-like phenotype. This was associated with increased expression of miR-145, a miRNA predicted in silico to target multiple components of the TGF-ß signalling pathway. miR-145 was also overexpressed in CAF derived from oral cancers. Overexpression of miR-145 blocked TGF-ß1-induced myofibroblastic differentiation and reverted CAF towards a normal fibroblast phenotype. We conclude that miR-145 is a key regulator of the CAF phenotype, acting in a negative feedback loop to dampen acquisition of myofibroblastic traits, a key feature of CAF associated with poor disease outcome.