Project description:Extracellular vesicles (EVs) are particles of different sizes, covered by a lipid bilayer membrane and containing highly heterogeneous cargo. Cancer cell-derived EVs have been the main object of an extensive investigation in the field because they carry cancer-specific molecular cargo and can promote cancer progression. Cancer-derived EVs include populations of atypically large EVs (L-EVs) that can be pelleted by a low/medium speed centrifugation, which have been referred to as tumor microvesicles, large oncosomes, or simply L-EVs. While small EVs (S-EVs), which pellet at a high speed centrifugation and include exosomes, have been investigated by a plethora of reports, little is known about the cargo of L-EVs. The paucity of studies comparing protein cargo of L- and S-EVs, of studies focused on protein coding RNA, and the absence of integrative analyses to compare the protein and gene expression in different EV fractions, prompted us to perform mass spectrometry to profile three different, size-based EV fractions generated by three cancer cell models (glioma, prostate and breast cancer). We identified general as well as cancer type-specific protein signatures for L- and S-EVs. A subset of the proteins enriched in prostate cancer cell-derived L-EVs was also identified in L-EVs from plasma of patients with metastatic prostate cancer by an independent Sequential Window Acquisition of All Theoretical Mass Spectra (SWATH) mass spectrometry analysis. Proteomic and transcriptomic analyses of the prostate cancer-derived EVs revealed an enrichment of mitochondrial functions in L-EVs versus S-EVs at both the protein and RNA level. The mitochondrial signature was confirmed in L-EVs by single EV RNA-Seq. The integrated L-EV proteomic and transcriptomic signature enabled distinction between benign and localized prostate cancer, as well as between localized cancer and metastatic castration-resistant cancer.

Project description:Extracellular vesicles (EVs) are membrane-encapsulated particles that vary greatly in size and content. Although both normal and tumor cells produce an array of small EVs (S-EVs), only tumor cells have been found to release a population of atypically large EVs (L-EVs), also known as large oncosomes (LO). Little is known about the cargo of L-EVs, and how it differs from the S-EVs. Given the potential for tumor-derived L-EVs to provide insights into disease mechanisms and course, we performed proteomic analysis of L- and S-EVs derived from three cancer models followed by comparative proteomic and transcriptomic analysis of EVs from the prostate cancer model. 1) We identified both common and model-specific protein signatures for L- and S-EVs. 2) A subset of the proteins enriched in prostate cancer cell-derived L-EVs were also identified in L-EVs isolated from plasma of patients with metastatic prostate cancer. 3) Proteins enriched in L-EV that were also identified at the transcript level were mostly mitochondrial in origin, as confirmed by single vesicle RNA-Seq. Additionally, the L-EV mitochondrial signature was detected in plasma-derived L-EVs and distinguished patients with prostate cancer from cancer-free individuals as well as patients with metastatic prostate cancer from those with localized disease, corroborating the relevance of an integrative multi-analyte approach focused on L-EVs for liquid biopsy.

Project description:Extracellular Vesicles (EVs) are particles of different sizes, covered by a lipid bilayer membrane and containing highly heterogeneous cargo. Cancer cell-derived EVs have been the main object of an extensive investigation in the field because they carry cancer-specific molecular cargo and can promote cancer progression. Cancer-derived EVs include populations of atypically large EVs (L-EVs), which have been referred to as tumor microvesicles, large oncosomes, or simply L-EVs. While small EVs (S-EVs), which include exosomes, have been investigated by a plethora of reports, little is known about L-EVs. The paucity of studies comparing protein cargo of L- and S-EVs, of studies focused on protein coding RNA, and the absence of integrative analyses to compare the protein and gene expression in different EV fractions, prompted us to perform mass spectrometry to profile three different, size-based EV fractions generated by three cancer cell models (glioma, prostate and breast cancer). We identified protein signatures for L- and S-EVs either common to all cell types or specific to each of them individually. The proteins enriched in prostate cancer cell-derived L-EVs were also identified in L-EVs from patients with metastatic prostate cancer by a SWATH proteomic assay. We also performed RNA-Seq on the prostate cancer model and integrated proteomic and transcriptomic datasets. GSEA revealed that mitochondrial function was enriched in L-EVs versus S-EVs at both the RNA and protein level. The mitochondrial signature at the transcriptome level was confirmed by single cell RNA-Seq of L- EVs in vitro. The integrated L-EV proteomic and transcriptomic signature enabled distinction between benign and localized prostate cancer, as well as between localized cancer and metastatic castration-resistant cancer.

Project description:Beyond forming bone, osteoblasts play pivotal roles in various biological processes, including hematopoiesis and bone metastasis. Extracellular vesicles (EVs) have recently been implicated in intercellular communication via transfer of proteins and nucleic acids between cells. Here, we focused on the proteomic characterization of non-mineralizing (NMOBs) and mineralizing (MOBs) human osteoblast (SV-HFOs) EVs and investigated their effect on human prostate cancer (PC3) cells by microscopic, proteomic and gene expression analyses. Proteomic analysis showed that 97% of the proteins were shared among NMOB and MOB EVs, and 30% were novel osteoblast-specific EV proteins. Label-free quantification demonstrated mineralization stage-dependent five-fold enrichment of 59 and 451 EV proteins in NMOBs and MOBs, respectively. Interestingly, bioinformatic analyses of the osteoblast EV proteomes and EV-regulated prostate cancer gene expression profiles showed that they converged on pathways involved in cell survival and growth. This was verified by in vitro proliferation assays where osteoblast EV uptake led to two-fold increase in PC3 cell growth compared to cell-free culture medium-derived vesicle controls. Our findings elucidate the mineralization stage-specific protein content of osteoblast-secreted EVs, show a novel way by which osteoblasts communicate with prostate cancer, and open up innovative avenues for therapeutic intervention. PC3 cells were treated with extracellular vesicles from non-mineralizing and mineralizing SV-HFOs for three different incubation times (4hrs, 24hrs, 48hr)

Project description:Extracellular vesicles (EVs) are membranous structures of variable size, shed from diverse cell types including highly invasive, fast migrating, amoeboid tumor cells. Silencing of the Diaphanous-related formin-3 (DIAPH3) protein in DU145 prostate cancer cells induces an amoeboid phenotype characterized by membrane blebbing and shedding of an atypically large population of EVs termed large oncosomes. We employed this cell system to characterize, for the first time, the global protein composition of large oncosomes and small EVs. The salient finding of this study, revealed by SILAC-based LC-MS/MS analysis was the identification of 20 unique proteins in large oncosomes and 7 in small EVs. Additionally, both types of EV were significantly enriched in proteins with cancer-related functions, suggesting that tumor interactions with the microenvironment are influenced by EV cargo. Proteins belonging to a series of functional classes, including GTPases, ESCRTs, RNA-binding proteins and membrane proteins, often identified in and which are sometimes considered specific for exosomes, appeared in both EV populations. Proteins such as CK18 and FN1, significantly enriched in large oncosomes, were selected to develop an assay to detect large oncosomes in the circulation. Finally, proteins over-represented in large oncosomes versus small EVs with at least a four-fold enrichment were significantly associated with cell migration, docetaxel resistance, angiogenesis, and prostate cancer bone metastasis, suggesting a distinct functional role in tumor progression for this larger class of EV. These observations indicate that, despite their origination from the same cell donors, the two distinct EV populations are enriched in different proteins and contribute diversified functions. These findings underscore the need for additional in-depth analyses to understand the unique contribution of subpopulations of EVs to tumor progression.

Project description:Idiopathic pulmonary fibrosis (IPF) is a lethal chronic lung disease characterized by aberrant intercellular communication, extracellular matrix deposition and destruction of functional lung tissue. While extracellular vesicles (EVs) accumulate in the IPF lung, their cargo and biological effects remain unclear. We interrogated the proteome of EV and non-EV fractions during pulmonary fibrosis and characterize their contribution to fibrosis. EVs accumulated 14 days post-bleomycin challenge, correlating with decreased lung function and initiated fibrogenesis in healthy precision-cut lung slices. Label-free proteomics of broncho-alveolar lavage fluid (BALF)-EVs collected from mice challenged with bleomycin or control identified 107 proteins enriched in fibrotic vesicles. Multiomic analysis revealed fibroblasts as a major cellular source of BALF-EV cargo, which was enriched in Secreted Frizzled Related Protein 1 (SFRP1). Sfrp1 deficiency inhibited the activity of fibroblast-derived EVs to potentiate lung fibrosis in vivo. SFRP1 led to increased transitional cell markers, such as Krt8, and WNT/β-catenin signaling in primary alveolar type 2 cells. SFRP1 is expressed within the IPF lung and localized at the surface of EVs from patient-derived fibroblasts and BALF. Our work reveals altered EV protein cargo in fibrotic EVs promoting fibrogenesis and identifies fibroblast derived vesicular SFRP1 as fibrotic mediator and potential therapeutic target for IPF.

Project description:Beyond forming bone, osteoblasts play pivotal roles in various biological processes, including hematopoiesis and bone metastasis. Extracellular vesicles (EVs) have recently been implicated in intercellular communication via transfer of proteins and nucleic acids between cells. Here, we focused on the proteomic characterization of non-mineralizing (NMOBs) and mineralizing (MOBs) human osteoblast (SV-HFOs) EVs and investigated their effect on human prostate cancer (PC3) cells by microscopic, proteomic and gene expression analyses. Proteomic analysis showed that 97% of the proteins were shared among NMOB and MOB EVs, and 30% were novel osteoblast-specific EV proteins. Label-free quantification demonstrated mineralization stage-dependent five-fold enrichment of 59 and 451 EV proteins in NMOBs and MOBs, respectively. Interestingly, bioinformatic analyses of the osteoblast EV proteomes and EV-regulated prostate cancer gene expression profiles showed that they converged on pathways involved in cell survival and growth. This was verified by in vitro proliferation assays where osteoblast EV uptake led to two-fold increase in PC3 cell growth compared to cell-free culture medium-derived vesicle controls. Our findings elucidate the mineralization stage-specific protein content of osteoblast-secreted EVs, show a novel way by which osteoblasts communicate with prostate cancer, and open up innovative avenues for therapeutic intervention.

Project description:The nematode Caenorhabditis elegans has evolutionarily conserved EV signaling pathways. In this study, we apply a recently published method for high specificity purification of EVs from C. elegans to carry out target-independent proteomic and RNA analysis of EVs from C. elegans. Our experiments uncovered diverse coding and non-coding RNA transcripts as well as protein cargo types commonly found in human EVs.

Project description:Much recent work has been dedicated to exploring the utility of extracellular vesicles (EVs) as circulating cancer biomarkers. This is driven by the understanding that the molecular cargo of EVs reflects their originating cell, meaning EVs may enable non-invasive tumour surveillance. Few attempts have been made, however, to empirically validate this assumption on the -omic level and define the relationship between the molecular phenotype of cells and EVs. To this end, we present an integrative multi-omic analysis of a panel of breast cancer cell lines and corresponding EVs. Transcriptomic analysis of the cells was first used to confirm that expression of disease-related transcripts remained stable following transition to a low serum EV production medium. Proteomic analysis of the EVs indicated that neither the ER nor PR protein could be directly detected in EVs, but cellular expression of ER could be indirectly inferred from the EV proteome. Transcriptomic analyses generally suggested a direct positive correlation between transcript levels in cells and EVs. Integrative analysis suggested that the EV proteome and transcriptome captured select hallmarks of aberrant pathway activity in the originating cells, supporting the potential use of EVs to non-invasively monitor molecular evolution in breast cancers.

Project description:Background: Human milk extracellular vesicles (EVs) affect various cell types in the gastrointestinal tract, including T cells, and play a role in the development of the newborn’s immune system by delivering specific molecular cargo to target cells. Although maternal allergic sensitization alters the composition of milk, it is unknown whether this impacts the function of milk EVs. Therefore, we analyzed the T cell modulatory capacity and compared the protein and miRNA cargo of EVs from milk of allergic and non-allergic mothers. Methods: EVs were isolated from human milk from allergic and non-allergic donors by differential centrifugation, density gradient floatation and size exclusion chromatography. Functional modulation of primary human CD4+ T cells by EVs was assessed in vitro. Proteomic analysis and small RNA sequencing was performed on milk EVs to evaluate protein and miRNA abundance and to identify cellular targets of this EV cargo in relevant T cell signaling pathways. Results: T cell proliferation, activation and cytokine production were suppressed in the presence of milk EVs. Remarkably, milk EVs from allergic mothers modulated T cell activation to a lesser extent than EVs from non-allergic mothers. Integrative multi-omics analysis identified EV cargo of which the cellular targets could be linked to T cell activation-associated processes. Conclusions: Milk EVs from non-allergic mothers are stronger inhibitors of T cell activation compared to milk EVs from allergic mothers. This altered functionality might be linked to small changes in modulation of certain T cell signaling pathways.