Extracellular vesicles represent a rich source of novel biomarkers in the diagnosis and prognosis of disease. However, there is currently limited information elucidating the most efficient methods for obtaining high yields of pure exosomes, a subset of extracellular vesicles, from cell culture supernatant and complex biological fluids such as plasma. To this end, we comprehensively characterize a variety of exosome isolation protocols for their efficiency, yield and purity of isolated exosomes. Repeated ultracentrifugation steps can reduce the quality of exosome preparations leading to lower exosome yield. We show that concentration of cell culture conditioned media using ultrafiltration devices results in increased vesicle isolation when compared to traditional ultracentrifugation protocols. However, our data on using conditioned media isolated from the Non-Small-Cell Lung Cancer (NSCLC) SK-MES-1 cell line demonstrates that the choice of concentrating device can greatly impact the yield of isolated exosomes. We find that centrifuge-based concentrating methods are more appropriate than pressure-driven concentrating devices and allow the rapid isolation of exosomes from both NSCLC cell culture conditioned media and complex biological fluids. In fact to date, no protocol detailing exosome isolation utilizing current commercial methods from both cells and patient samples has been described. Utilizing tunable resistive pulse sensing and protein analysis, we provide a comparative analysis of 4 exosome isolation techniques, indicating their efficacy and preparation purity. Our results demonstrate that current precipitation protocols for the isolation of exosomes from cell culture conditioned media and plasma provide the least pure preparations of exosomes, whereas size exclusion isolation is comparable to density gradient purification of exosomes. We have identified current shortcomings in common extracellular vesicle isolation methods and provide a potential standardized method that is effective, reproducible and can be utilized for various starting materials. We believe this method will have extensive application in the growing field of extracellular vesicle research.
Small membranous secretions from tumor cells, termed exosomes, contribute significantly to intercellular communication and subsequent reprogramming of the tumor microenvironment. Here, we use optical imaging to determine that exogenously administered fluorescently labeled exosomes derived from highly metastatic murine breast cancer cells distributed predominantly to the lung of syngeneic mice, a frequent site of breast cancer metastasis. At the sites of accumulation, exosomes were taken up by CD45 bone marrow-derived cells. Subsequent long-term conditioning of naïve mice with exosomes from highly metastatic breast cancer cells revealed the accumulation of myeloid-derived suppressor cells in the lung and liver. This favorable immune suppressive microenvironment was capable of promoting metastatic colonization in the lung and liver, an effect not observed from exosomes derived from nonmetastatic cells and liposome control vesicles. Furthermore, we determined that breast cancer exosomes directly suppressed T-cell proliferation and inhibited NK cell cytotoxicity, and hence likely suppressed the anticancer immune response in premetastatic organs. Together, our findings provide novel insight into the tissue-specific outcomes of breast cancer-derived exosome accumulation and their contribution to immune suppression and promotion of metastases. Cancer Res; 76(23); 6816-27. ©2016 AACR.
This article is available online at http://www.jlr.org developed very early during evolution. Cytosolic lipid droplets (LDs) are the main reservoir of lipids and are common to many if not all eukaryotic cells ( 1 ). LDs have gained much recent interest because of their regulatory role in lipid homeostasis and their implication in metabolic diseases such as obesity and type 2 diabetes ( 2-4 ). They have a unique structure composed of a hydrophobic core surrounded by a phospholipid monolayer containing a specifi c protein composition. Perilipin family proteins and lipid metabolizing enzymes are the most abundant proteins ( 5, 6 ), and proteomic studies have identifi ed many additional constituents ( 7 ). Little is known how proteins are specifi cally targeted to lipid droplets ( 8, 9 ). The biogenesis of LDs likely involves the endoplasmic reticulum, but the mechanism has not been solved and is debated intensely ( 2,3,10 ).Triglycerides are the main species of neutral lipids stored within the LDs of most cell types. The predominant biosynthetic pathway requires three activated fatty acids for each triglyceride molecule. The fatty acids are taken up from the extracellular medium or are derived from endogenous metabolism by fatty acid synthase. In fact, addition of fatty acids is a very effi cient way to induce the formation of LDs ( 4 ). However, fatty acids are chemically quite inert and need to be activated by esterifi cation with CoA ( 11 ). This activation is catalyzed by the family of acylCoA synthetases ( 12 ); physiologically highly relevant are the long chain (ACSL1, -3, -4, -5, -6) and very long chain (ACSVL1, -2, -3, -4, -5, and -6) fatty acyl-CoA synthetase subfamilies ( 13 ). Apart from their obvious enzymatic role, additional functions have been suggested for ACS(V)L family proteins: metabolic channeling of fatty acids toward specifi c metabolic fates [e.g., phospholipid synthesis vs.Abstract Cytosolic lipid droplets (LDs) are storage organelles for neutral lipids derived from endogenous metabolism. Acyl-CoA synthetase family proteins are essential enzymes in this biosynthetic pathway, contributing activated fatty acids. Fluorescence microscopy showed that ACSL3 is localized to the endoplasmic reticulum (ER) and LDs, with the distribution dependent on the cell type and the supply of fatty acids. The N-terminus of ACSL3 was necessary and sufficient for targeting reporter proteins correctly, as demonstrated by subcellular fractionation and confocal microscopy. The N-terminal region of ACSL3 was also found to be functionally required for the enzyme activity. Selective permeabilization and in silico analysis suggest that ACSL3 assumes a hairpin membrane topology, with the N-terminal hydrophobic amino acids forming an amphipathic helix restricted to the cytosolic leafl et of the ER membrane. ACSL3 was effectively translocated from the ER to nascent LDs when neutral lipid synthesis was stimulated by the external addition of fatty acids. Cellular fatty acid uptake was increased by overexpression and reduced b...
Transorbital penetrating brain injuries are treated best by utilizing all up-to-date technical developments such as intraoperative CT-scanning to increase the safety in the management of such exceptional lesions with increased risk of immediate life-threatening intracranial bleeding.
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