Avaliação do perfil de microRNAs exossomais em portadores de hipercolesterolemia familial / Evaluation of the profile of exosomal microRNAs in patients with familial hypercholesterolemia

A Hipercolesterolemia Familial (HF) é uma doença hereditária do metabolismo lipídico que causa aos portadores alta incidência de aterosclerose prematura. A HF pode ser diagnosticada clínica e geneticamente, entretanto, apenas cerca de 40% podem ter confirmados pelo diagnostico molecular. Assim, outros sistemas de diagnóstico devem ser avaliados. Ultimamente devido a estabilidade em fluidos biológicos, os exossomos circulantes apresentam grande potencial, pois carreiam um número variado de compostos e são considerados veículos de intercomunicação entre os tecidos. Sabe-se que vários RNAs são carreados nos exossomos, incluindo miRNAs, lncRNA e uma variedade de proteínas. Estes componentes podem ser marcadores de diagnóstico para várias doenças inclusive a HF e suas complicações cardiovasculares. Foram utilizadas amostras de exossomos plasmáticos provenientes de 54 pacientes HF sem uso de estatina por, no mínimo, seis semanas, e 38 indivíduos normolipidêmicos para sequenciamento de miRNAs e estudo da proteômica. Os exossomos foram isolados utilizando dois métodos precipitação química e cromatográfica de exclusão de tamanho e caraterizados utilizando: dispersão de luz dinâmica, Western blotting, rastreamento de nanopartículas (NanoSight), imunomarcação e microscopia eletrônica de transmissão. Os miRNAs e proteínas foram extraídos dos exossomos e analisados por sequenciamento de nova geração e espectrometria de massa, respectivamente. Os dados clínicos, biodemográficos e laboratoriais dos pacientes HF e controles indicaram diferenças significativas esperadas entre os grupos, indicando que foram selecionados adequadamente. A caracterização físico-química dos exossomos mostrou resultados com tamanho de ˜90nm e imunorreação positiva para tetraspaninas. O resultado do sequenciamento identificou acima 2000 miRNAs. Os miR-122- 5p e miR-21-5p apresentaram expressão aumentada no grupo HF (log2FC=1,79 e log2FC=1,27, respectivamente), e o miR-122-5p pós normalização em relação ao controle manteve significativo comparados ao controle (p=0,034). A análise comparativa entre exossomos e plasma total mostrou diferença significativa, pois foram identificadas 239 proteínas (p <0,05) diferentes entre exossomos e plasma. Em exossomos, 17 proteínas foram aumentadas e 21 diminuídas em pacientes com HF em comparação com o controle (p <0,05). Destas, seis proteínas foram mais abundantes em HF e sete proteínas foram menos abundantes em exossomos de pacientes com HF em comparação com o controle. A análise de enriquecimento por bioinformática mostrou que a maior parte dessas moléculas (miRNAs e proteínas) foram relacionadas com metabolismo lipídico, dislipidemia, aterosclerose, doença arterial coronariana, adipogênese. Assim, na busca de novos alvos como potenciais biomarcadores de diagnóstico da HF, nossos resultados da análise integrativa entre os miRNAs e as proteínas exossomais abre novas frentes de pesquisa mais bem direcionadas, para a validação desses miRNAs e proteínas exossomais

Familial Hypercholesterolemia (FH) is an inherited disease of lipid metabolism that causes a high incidence of premature atherosclerosis in patients. FH can be diagnosed clinically and genetically, however, only about 40% can be confirmed by molecular diagnosis. Thus, other diagnostic systems should be evaluated. Lately, due to stability in biological fluids, circulating exosomes have great potential, as they carry a varied number of compounds and are considered vehicles of intercommunication between tissues. Several RNAs are known to be carried on exosomes, including miRNAs, lncRNA, and a variety of proteins. These components can be diagnostic markers for several diseases including FH and its cardiovascular complications. Plasma exosome samples from 54 FH patients without statin use for at least six weeks and 38 normolipidemic individuals were used for miRNA sequencing and proteomics studies. Exosomes were isolated using two methods chemical precipitation and size exclusion chromatography and characterized using: dynamic light scattering, Western blotting, nanoparticle tracking (NanoSight), immunostaining and transmission electron microscopy. MiRNAs and proteins were extracted from exosomes and analyzed by next-generation sequencing and mass spectrometry, respectively. Clinical, biodemographic and laboratory data of FH patients and controls indicated significant expected differences between the groups, indicating that they were appropriately selected. The physicochemical characterization of exosomes showed results with a size of ˜90nm and positive immunoreaction for tetraspanins. The sequencing result identified above 2000 miRNAs. miR-122-5p and miR-21-5p showed increased expression in the FH group (log2FC=1.79 and log2FC=1.27, respectively), and miR122-5p after normalization in relation to the control remained significant compared to the control (p=0.034). The comparative analysis between exosomes and total plasma showed a significant difference, as 239 different proteins (p < 0.05) were identified between exosome and plasma. In exosomes, 17 proteins were increased and 21 decreased in FH patients compared to control (p < 0.05). Of these, six proteins were more abundant in FH and seven proteins were less abundant in exosomes from patients with FH compared to the control. Bioinformatics enrichment analysis showed that most of these molecules (miRNAs and proteins) were related to lipid metabolism, dyslipidemia, atherosclerosis, coronary artery disease, adipogenesis. Thus, in the search for new targets as potential diagnostic biomarkers of FH, our results of the integrative analysis between miRNAs and exosomal proteins opens new and better-directed research fronts for the validation of these miRNAs and exosomal proteins

Label-Free Exosomal Detection and Classification in Rapid Discriminating Different Cancer Types Based on Specific Raman Phenotypes and Multivariate Statistical Analysis.

Exosomes contain different functional bimolecular characteristics related to physiological or pathological processes and are now recognized as new biomarkers in different human cancers. Rapid detection and classification of cancer-related exosomes might be helpful in the rapid screening of patients that may have cancer. Here, we report a surface enhanced Raman scattering technology for rapid and label-free exosomal detection (Exo-SERS) to aid in the discrimination of different cancer cells based on specific Raman phenotypes and multivariate statistical analysis. The results demonstrated that exosomes derived from both tumor cells and normal cells exhibit special, unique Raman phenotypes. Using the Exo-SERS method, the cancer cells were accurately discriminated from normal cells, and subtle molecular changes between the different cell types could be detected with high sensitive. This research provides a rapid, label-free and non-destructive manner for detecting and discriminating between cancer types.

Characterization and Therapeutic Uses of Exosomes: A New Potential Tool in Orthopedics.

In recent years, regenerative medicine has directed its interests onto the use of stem cells to heal human tissues. One specific class of cells that has been used in this field of research is mesenchymal stem cells (MSCs). Because of difficulties with the usage of whole stem cells, researchers have turned to an alternative, the secretome of the MSCs. In recent years, research has explored numerous aspects of the MSC secretome, especially the most promising aspect, exosomes. This review explores a variety of interests in exosomes including the classification and molecular composition of exosomes, mechanisms for exosome isolation, and the various biological functions of exosomes. As more is discovered about the exosomes, their different diagnostic and therapeutic uses in the medical field have also been explored. A new field attempting to exploit the exosomes in clinical practice is orthopedics. Although a significant deal of research has been carried out, even more is being discovered to allow utilization of the exosomes in clinical practice.

Rapid Differentiation of Host and Parasitic Exosome Vesicles Using Microfluidic Photonic Crystal Biosensor.

Parasite extracellular vesicles (EVs) are potential biomarkers that could be exploited for the diagnosis of infectious disease. This paper reports a rapid bioassay to discriminate parasite and host EVs. The EV detection assay utilizes a label-free photonic crystal (PC) biosensor to detect the EVs using a host-specific transmembrane protein (CD63), which is present on EV secreted by host cells (modeled by murine macrophage cell line J774A.1) but is not expressed on EV secreted by parasitic nematodes such as the gastrointestinal nematode Ascaris suum. The surface of PC is functionalized to recognize CD63, and is sensitive to the changes in refractive index caused by the immobilization of EVs. The biosensor demonstrates a detection limit of 2.18 × 109 EVs/mL and a capability to characterize the affinity constants of antibody-host EV bindings. The discrimination of murine host EVs from parasite EVs indicates the capability of the sensor to differentiate EVs from different origins. The label-free, rapid EV assay could be used to detection parasite infection and facilitate the exosome-based clinic diagnosis and exosome research.

Identification of distinct nanoparticles and subsets of extracellular vesicles by asymmetric flow field-flow fractionation.

The heterogeneity of exosomal populations has hindered our understanding of their biogenesis, molecular composition, biodistribution and functions. By employing asymmetric flow field-flow fractionation (AF4), we identified two exosome subpopulations (large exosome vesicles, Exo-L, 90-120 nm; small exosome vesicles, Exo-S, 60-80 nm) and discovered an abundant population of non-membranous nanoparticles termed 'exomeres' (~35 nm). Exomere proteomic profiling revealed an enrichment in metabolic enzymes and hypoxia, microtubule and coagulation proteins as well as specific pathways, such as glycolysis and mTOR signalling. Exo-S and Exo-L contained proteins involved in endosomal function and secretion pathways, and mitotic spindle and IL-2/STAT5 signalling pathways, respectively. Exo-S, Exo-L and exomeres each had unique N-glycosylation, protein, lipid, DNA and RNA profiles and biophysical properties. These three nanoparticle subsets demonstrated diverse organ biodistribution patterns, suggesting distinct biological functions. This study demonstrates that AF4 can serve as an improved analytical tool for isolating extracellular vesicles and addressing the complexities of heterogeneous nanoparticle subpopulations.

Extracellular vesicles from activated platelets: a semiquantitative cryo-electron microscopy and immuno-gold labeling study.

Cells release membrane vesicles in their surrounding medium either constitutively or in response to activating signals. Two main types of extracellular vesicles (EVs) are commonly distinguished based on their mechanism of formation, membrane composition and size. According to the current model, EVs shed from the plasma membrane, often called microvesicles, expose phosphatidylserine (PS) and range in size from 100 nm to 1 µm, while EVs originating from endosomal multi-vesicular bodies, called exosomes, contain tetraspanin proteins, including CD63, and range in size from 50 to 100 nm. Heijnen et al. [1] have shown that activated platelets release EVs corresponding to these two types of vesicles, using negative staining electron microscopy (EM) and immuno-gold labeling. Here, we apply cryo-EM and immuno-gold labeling to provide a quantitative analysis of EVs released by platelets activated by thrombin, TRAP and CRP-XL, as well as EVs from serum. We show that EVs activated by these three agonists present a similar size distribution, the majority of them forming a broad peak extending from 50 nm to 1 µm, about 50% of them ranging from 50 to 400 nm. We show also that 60% of the EVs from TRAP or CRP-XL activation expose CD41, a majority of them exposing also PS. To explain the presence of large EVs CD41-negative or PS-negative, several alternative mechanisms of EV formation are proposed. We find also that the majority of EVs in activated platelet samples expose CD63, and distinguish two populations of CD63-positive EVs, namely large EVs with low labeling density and small EVs with high labeling density.

Biobanking of Exosomes in the Era of Precision Medicine: Are We There Yet?

The emerge of personalized medicine demands high-quality human biospecimens with appropriate clinical annotation, especially in complex diseases such as cancer, neurodegenerative, cardiovascular, and metabolic alterations in which specimen heterogeneity and individual responses often complicate the development of precision therapeutic programs. In the growing field of extracellular vesicles (EVs) research, exosomes (EXOs)--a particular type of EVs--have been proposed as an advantageous diagnostic tool, as effective delivery vehicles and as therapeutic targets. However, the lack of consensus on isolation methods and rigorous criteria to characterize them puts the term EXO into question at the time that might explain some of the controversial results found in the literature. A lack of response in the biobank network to warrant standard optimized procedures for the isolation, characterization, and storage of EXOs will undoubtedly lead to a waste of resources and failure. This review is aimed at highlighting the increasing importance of EXOs for the clinic, especially in the cancer field, and at summarizing the initiatives taken to improve current isolation procedures, classification criteria, and storage conditions of EXOs as an effort to identify technological demands that biobank platforms face for the incorporation of EXOs and other extracellular vesicle fractions as valuable biospecimens for research.

Identification and staining of distinct populations of secretory organelles in astrocytes.

Increasing evidence indicates that astrocytes, the most abundant glial cell type in the brain, respond to an elevation in cytoplasmic calcium concentration ([Ca(2+)]i) by releasing chemical transmitters (also called gliotransmitters) via regulated exocytosis of heterogeneous classes of organelles. By this process, astrocytes exert modulatory influences on neighboring cells and are thought to participate in the control of synaptic circuits and cerebral blood flow. Studying the properties of exocytosis in astrocytes is a challenge, because the cell biological basis of this process is incompletely defined. Astrocytic exocytosis involves multiple populations of secretory vesicles, including synaptic-like microvesicles (SLMVs), dense-core granules (DCGs), and lysosomes. Here we summarize the available information for identifying individual populations of secretory organelles in astrocytes, including DCGs, SLMVs, and lysosomes, and present experimental procedures for specifically staining such populations.

Emerging technologies in extracellular vesicle-based molecular diagnostics.

Extracellular vesicles (EVs), including exosomes and microvesicles, have been shown to carry a variety of biomacromolecules including mRNA, microRNA and other non-coding RNAs. Within the past 5 years, EVs have emerged as a promising minimally invasive novel source of material for molecular diagnostics. Although EVs can be easily identified and collected from biological fluids, further research and proper validation is needed in order for them to be useful in the clinical setting. In addition, innovative and more efficient means of nucleic acid profiling are needed to facilitate investigations into the cellular and molecular mechanisms of EV function and to establish their potential as useful clinical biomarkers and therapeutic tools. In this article, we provide an overview of recent technological improvements in both upstream EV isolation and downstream analytical technologies, including digital PCR and next generation sequencing, highlighting future prospects for EV-based molecular diagnostics.

Two distinct populations of exosomes are released from LIM1863 colon carcinoma cell-derived organoids.

Exosomes are naturally occurring biological nanomembranous vesicles (∼40 to 100 nm) of endocytic origin that are released from diverse cell types into the extracellular space. They have pleiotropic functions such as antigen presentation and intercellular transfer of protein cargo, mRNA, microRNA, lipids, and oncogenic potential. Here we describe the isolation, via sequential immunocapture using anti-A33- and anti-EpCAM-coupled magnetic beads, of two distinct populations of exosomes released from organoids derived from human colon carcinoma cell line LIM1863. The exosome populations (A33-Exos and EpCAM-Exos) could not be distinguished via electron microscopy and contained stereotypical exosome markers such as TSG101, Alix, and HSP70. The salient finding of this study, revealed via gel-based LC-MS/MS, was the exclusive identification in EpCAM-Exos of the classical apical trafficking molecules CD63 (LAMP3), mucin 13 and the apical intestinal enzyme sucrase isomaltase and increased expression of dipeptidyl peptidase IV and the apically restricted pentaspan membrane glycoprotein prominin 1. In contrast, the A33-Exos preparation was enriched with basolateral trafficking molecules such as early endosome antigen 1, the Golgi membrane protein ADP-ribosylation factor, and clathrin. Our observations are consistent with EpCAM- and A33-Exos being released from the apical and basolateral surfaces, respectively, and the EpCAM-Exos proteome profile with widely published stereotypical exosomes. A proteome analysis of LIM1863-derived shed microvesicles (sMVs) was also performed in order to clearly distinguish A33- and EpCAM-Exos from sMVs. Intriguingly, several members of the MHC class I family of antigen presentation molecules were exclusively observed in A33-Exos, whereas neither MHC class I nor MHC class II molecules were observed via MS in EpCAM-Exos. Additionally, we report for the first time in any extracellular vesicle study the colocalization of EpCAM, claudin-7, and CD44 in EpCAM-Exos. Given that these molecules are known to complex together to promote tumor progression, further characterization of exosome subpopulations will enable a deeper understanding of their possible role in regulation of the tumor microenvironment.

Classification, functions, and clinical relevance of extracellular vesicles.

Both eukaryotic and prokaryotic cells release small, phospholipid-enclosed vesicles into their environment. Why do cells release vesicles? Initial studies showed that eukaryotic vesicles are used to remove obsolete cellular molecules. Although this release of vesicles is beneficial to the cell, the vesicles can also be a danger to their environment, for instance in blood, where vesicles can provide a surface supporting coagulation. Evidence is accumulating that vesicles are cargo containers used by eukaryotic cells to exchange biomolecules as transmembrane receptors and genetic information. Because also bacteria communicate to each other via extracellular vesicles, the intercellular communication via extracellular cargo carriers seems to be conserved throughout evolution, and therefore vesicles are likely to be a highly efficient, robust, and economic manner of exchanging information between cells. Furthermore, vesicles protect cells from accumulation of waste or drugs, they contribute to physiology and pathology, and they have a myriad of potential clinical applications, ranging from biomarkers to anticancer therapy. Because vesicles may pass the blood-brain barrier, they can perhaps even be considered naturally occurring liposomes. Unfortunately, pathways of vesicle release and vesicles themselves are also being used by tumors and infectious diseases to facilitate spreading, and to escape from immune surveillance. In this review, the different types, nomenclature, functions, and clinical relevance of vesicles will be discussed.

Exosomes: extracellular organelles important in intercellular communication.

In addition to intracellular organelles, eukaryotic cells also contain extracellular organelles that are released, or shed, into the microenvironment. These membranous extracellular organelles include exosomes, shedding microvesicles (SMVs) and apoptotic blebs (ABs), many of which exhibit pleiotropic biological functions. Because extracellular organelle terminology is often confounding, with many preparations reported in the literature being mixtures of extracellular vesicles, there is a growing need to clarify nomenclature and to improve purification strategies in order to discriminate the biochemical and functional activities of these moieties. Exosomes are formed by the inward budding of multivesicular bodies (MVBs) and are released from the cell into the microenvironment following the fusion of MVBs with the plasma membrane (PM). In this review we focus on various strategies for purifying exosomes and discuss their biophysical and biochemical properties. An update on proteomic analysis of exosomes from various cell types and body fluids is provided and host-cell specific proteomic signatures are also discussed. Because the ectodomain of ~42% of exosomal integral membrane proteins are also found in the secretome, these vesicles provide a potential source of serum-based membrane protein biomarkers that are reflective of the host cell. ExoCarta, an exosomal protein and RNA database (http://exocarta.ludwig.edu.au), is described.