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 and studies focusing 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: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:We performed whole transcriptome sequencing of human monocytes that were co-cultured with estrogen receptor positive (ER+) or triple-negative (TNBC) breast cancer cell lines and studied the biological responses related to the differential gene activation in both cell types to understand how different cancer cells educate host cells to support tumor growth To characterize the differences in macrophage activation under the influence of either ER+ or TNBC breast cancer cells, we cultured freshly isolated human peripheral monocytes with two breast cancer cell lines (T47D, ER+ and MDA-MB-231, TNBC) in an in vitro transwell co-culture assay. The transwell setting allowed us to investigate the effect of soluble mediators on macrophage activation since direct cell contact of these cells was inhibited by a (PET) membrane (pore size 0.4 μm).

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: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:RNA expression patterns of breast cell lines were compared with a breast cell line mixed reference. Gene expression profiles of 52 individual breast cell lines relative to a breast cell line reference mix containing equal amounts of 10 breast cell lines.

Project description:Circulating extracellular vesicles (EVs) contain molecular footprints - lipids, proteins, metabolites, RNA, and DNA - from their cell of origin and may provide non-invasive access for detection, characterization, and monitoring of diseases. Consequently, EV-associated RNA and proteins have gained widespread interest in developing liquid-biopsy assays for cancer. Yet, an integrative proteo-transcriptomic landscape of EVs and a direct comparison with their cell of origin remains relatively unexplored. Here, we report that EVs enrich for distinct molecular cargo and their proteo-transcriptome does not linearly correlate with their cell of origin. Our sub-cellular compartment analyses revealed that EV enrich 2-6 times more cytoskeletal and extracellular proteins, while their donor cells cargo 3-10 times more nuclear and mitochondrial proteins. EVs predominantly enrich (40-60%) for small RNA between ~15-200 nucleotides, which include miRNAs, siRNAs, tRNA, 5S rRNAs, and snRNAs, associated with cell differentiation, development, and Wnt signaling signatures. Finally, our integrated proteo-transcriptomic analyses reveal that EVs are enriched with specific small RNAs (RNY3, vtRNA, and MIRLET-7) and their complementary proteins (YBX1, IGF2BP2, SRSF1/2). These analyses suggest that RNA-protein complexes may constitute a functional interaction network inside EVs to protect and regulate access to EV-RNA. To ensure that our analyses are unbiased and independent of the cell of origin, EV isolation methods, site of experimentation, site of data generation, and methodologies applied for RNAseq and mass spectrometry, we have generated and curated comprehensive datasets of proteomics and transcriptomics from a total of 12 cancer cell lines, their EVs, and prostate cancer patientsÕ serum EVs (A detailed description is provided in Fig. 1). These combined analyses demonstrated that irrespective of the cell of origin and other aforementioned conditions, EVs enrich for distinct RNA and protein signatures that do not linearly correlate with their cell of origin.

Project description:Osteolineage cells represent one of the critical bone marrow niche components that support maintenance of hematopoietic stem and progenitor cells (HSPCs). Recent studies demonstrate that extracellular vesicles (EVs) regulate stem cell development via horizontal transfer of bioactive cargo, including microRNAs (miRNAs). Here, we characterize the miRNA profile of EVs secreted by human osteoblasts and study their biological effect of on human umbilical cord blood-derived CD34+ HSPCs by sequencing, gene expression and biochemical analyses. Using next-generation sequencing we show that osteoblast-derived EVs contain highly abundant miRNAs specifically enriched in EVs, including critical regulators of hematopoietic proliferation (e.g., miR-29a). EV treatment of CD34+ HSPCs alters the expression of candidate miRNA targets, such as HBP1, BCL2 and PTEN. Furthermore, EVs enhance proliferation of CD34+ cells and their immature subsets in growth factor-driven ex vivo expansion cultures. Importantly, EV-expanded cells retain their differentiation capacity in vitro and show successful engraftment in NOD.Cg-Prkdcscid Il2rgtm1Wjl/SzJ (NSG) mice in vivo. These discoveries reveal a novel osteoblast-derived EV-mediated mechanism for regulation of HSPC proliferation and warrant consideration of EV-miRNAs for the development of expansion strategies to treat hematological disorders.

Project description:The goal of this experiment is to explore the mechanism behind CITED2 (a non-DNA binding transcriptional co-activator) metastatic action by comparing gene expression changes between shScramble and shCITED2-expressing MDA-MB-231 cells.

Project description:Patient-derived prostate fibroblast primary cultures PCF-54 and PCF-55 were established from two specimens of PC tissues. Urinary EVs were isolated from urine samples of 3 patients with PC and 2 healthy males and used for the treatment of prostate fibroblast primary cultures and normal foreskin fibroblasts. Normoxic and hypoxic EVs were isolated from cell culture medium of PC3 and LNCaP prostate cancer cell lines, cultivated in normoxic and hypoxic conditions respectively. The EV-treated fibroblasts were subjected to RNA sequencing analysis.