Project description:Advances in understanding intercellular communication through extracellular vesicles (EVs) and non-vesicular extracellular nanoparticles (NVEPs) have been limited by their cellular heterogeneity and unclear origins. Using sequential ultracentrifugation, we identified high- and low-density EVs and performed multi-omics analyses on four EV/NVEP categories, including supermeres. Our findings reveal that extracellular RNA, RNA-binding proteins, and other cellular proteins are differentially expressed among EVs and NVEPs. Notably, supermeres can penetrate the blood-brain barrier, in a manner dependent on their intact RNA and protein structure, and distribute throughout the CNS. Supermeres preferentially interact with microglia at higher levels than other CNS cell types. These interactions lead to decreased TGFβ expression, suggesting an immunomodulatory role. This study highlights supermeres as a promising platform for CNS therapeutic delivery.

Project description:Extracellular vesicles (EVs) are lipid bilayered vesicles released into extracellular milieu by most of cells. Currently, various purification methods of EVs have been established but most of studies use ultracentrifugation-based purification of EVs. However, these methods have the problem of co-purification with non-vesicular contaminants including various different types of particles, small apoptotic vesicles, protein aggregates, and other derived from dead cells or abundant extracellular proteins. Therefore, evaluation of non-vesicular contaminants gives valuable information in EV research. Here, we purified EVs with high purity using density gradient ultracentrifugation and then purified EVs were treated by trypsin to discriminate extra-vesicular proteins from intra-vesicular proteins.

Project description:The cell seretome is diverse and contains extracellular secreted vesicles (EVs) as well as non-vesicular extracellular nanoparticles (NVEPs) called exomeres and supermeres, all of which carry different kinds of cell signaling cargos. We have developed new techniques to purify exomeres and supermeres by ultracentrifugation (UC) and by fast protein liquid chromatography (FPLC) from cell conditioned media and from blood plasma. We utilized a proteomics approach to compare UC and FPLC methods with standard UC and density gradient methods of isolating EVs and new methods of isolating NVEPs. We acquired LC-MS/MS data from conditioned media using standard 2D plastic and hollow fiber 3D bioreactor production from a CRC cell line, DiFi, using all these methods and growth culture conditions.

Project description:Pyroptosis—inflammatory cell death mediated by gasdermins (GSDM)—plays crucial roles in antimicrobial defense and inflammatory diseases. Pyroptosis results in the release of proinflammatory molecules, including damage-associated molecular patterns (DAMPs). However, our understanding of the consequences of pyroptosis—especially beyond IL-1 cytokines and DAMPs—that govern inflammation is limited. Here, we show intercellular propagation of pyroptosis from dying cells to bystander cells in vitro and in vivo. We identified extracellular vesicles (EVs) released by pyroptosing cells as the propagator of lytic death to naïve cells, triggering inflammatory responses and tissue damage. Remarkably, DNA-PAINT super-resolution and immunoelectron microscopical analyses revealed the presence of GSDMD nanostructures, such as pores, on EVs released by pyroptotic cells. Importantly, the transplantation of these GSDMD pores on adjacent cells’ plasma membrane by EVs causes cell-extrinsic lysis of bystanders. Overall, our findings demonstrate that cell-to-cell vesicular transplantation of GSDMD pores disseminates pyroptosis, revealing a domino-like effect shaping disease-associated bystander cell death.

Project description:The cell seretome is diverse and contains extracellular secreted vesicles (EVs) as well as non-vesicular extracellular nanoparticles (NVEPs) called exomeres and supermeres, all of which carry different kinds of cell signaling cargos. One supermere enriched cargo is transforming growth factor beta induced (TGFBi) protein. We have created TGFBi-neon green-His tagged expressing cell lines in the microsatellite stable (MSS) colorectal cancer cell line DiFi and another one in CC-CR cells with microsatellite instability (MSI). We have developed a fast protein liquid chromatography (FPLC) method for isolating EVs, exomeres and supermeres from biofluids. We used either FPLC or FPLC and then nickel columns that bind His tags to isolate supermeres from DiFi or CC-CR cells. We utilized a proteomics approach acquiring LC-MS/MS data to compare FPLC to FPLC and His tagged TGFBi-containing purified supermeres from DiFi and CC-CR cells. This was done using hollow fiber 3D bioreactor production of conditioned media from these cell lines.

Project description:The human amniotic membrane (hAM) is a valuable tissue in regenerative medicine due to its capacity to release cell-derived bioactive factors. Among these, microRNAs (miRNAs) play a critical role in modulating gene expression. This study aimed to comprehensively characterize the miRNA landscape of native viable hAM tissue and its secretome, with a focus on distinguishing between extracellular vesicles (EV)-associated and protein-bound miRNAs. We analyzed two anatomically and functionally distinct regions of the hAM, the reflected and placental amnion. After incubation of tissue biopsies ex vivo for 72 hours, vesicular and non-vesicular components in the conditioned medium were separated by size exclusion chromatography, and small RNA sequencing was performed on tissue and secretome fractions. Our analysis identified three main clusters of miRNA expression corresponding to tissue, EV-associated, and protein-bound fractions. We observed regional differences in miRNA expression between the reflected and placental amnion and identified miRNAs selectively released into EVs or protein-bound fractions. Data of gene ontology analysis suggest distinct biological roles for miRNA depending on the sample type. This dataset provides novel insights into the spatial and functional miRNA release profile of viable hAM and contributes to a better understanding of its regenerative potential.

Project description:Background: Exosomes and extracellular vesicles (EVs) are increasingly recognized as important sources of biomarkers for disease study and diagnosis. Results: A synthetic peptide, Vn96, allows for capture of EVs from biological fluids using basic laboratory equipment. Conclusion: The Vn96-captured EVs are qualitatively equivalent or superior to exosomes isolated by ultracentrifugation. Significance: The Vn96 peptide provides an effective affinity-capture method for the isolation of EVs from biological fluids. In order to compare different methods of exosome purification, we compared RNA content of exosomes purified with each method. We used two different breast cancer cell lines MCF7 and MDA-MB-231. We processed data in order to identify large RNAs as well as small RNA by using different methods for the alignment

Project description:Background: Exosomes and extracellular vesicles (EVs) are increasingly recognized as important sources of biomarkers for disease study and diagnosis. Results: A synthetic peptide, Vn96, allows for capture of EVs from biological fluids using basic laboratory equipment. Conclusion: The Vn96-captured EVs are qualitatively equivalent or superior to exosomes isolated by ultracentrifugation. Significance: The Vn96 peptide provides an effective affinity-capture method for the isolation of EVs from biological fluids.

Project description:MicroRNAs (miRNAs) are a class of small RNA molecules that regulate expression of specific mRNA targets. They can be released from cells, often encapsulated within extracellular vesicles (EVs), and therefore have the potential to mediate intercellular communication. It has been suggested that certain miRNAs may be selectively exported, although the mechanism has yet to be identified. Manipulation of the miRNA content of EVs will be important for future therapeutic applications. We therefore wished to assess which endogenous miRNAs are enriched in EVs and how effectively an overexpressed miRNA would be exported. Small RNA libraries from HEK293T cells and vesicles before or after transfection with a vector for miR-146 overexpression were analysed by deep sequencing. A subset of miRNAs was found to be enriched in EVs. The global expression data provided by deep sequencing confirms that specific miRNAs are enriched in EVs released by HEK293T cells. Cells were transfected with a plasmid to direct overexpression of miR-146a. Extracellular vesicles were isolated by ultracentrifugation from untreated and transfected cells. RNA was isolated from one sample each of untreated and transfected cells and vesicles.Small RNA libraries were prepared for sequencing.

Project description:In order to identify small RNAs that are enriched in T-cell extracellular vesicles (EVs) upon T cell activation in a nSMase-dependent manner, we used a two-step ultracentrifugation procedure to isolate EVs released by T cells followed by small RNA profiling of EVs and T cells under resting, stimulated conditions and stimulated conditions in the presence of the vehicle control, DMSO, or nSMase inhibitor, GM4869.