Literature DB >> 30533205

Essentials of extracellular vesicles: posters on basic and clinical aspects of extracellular vesicles.

Rienk Nieuwland^1,2, Juan Manuel Falcon-Perez^3,4, Carolina Soekmadji⁵, Eric Boilard^6,7, Dave Carter⁸, Edit I Buzas^9,10.

Abstract

The past decade has witnessed an exponential development in the field of extracellular vesicles. Sporadic observations have reached a critical level and the scientific community increasingly recognizes the potential biomedical significance of these subcellular structures present in all body fluids as significant components of the cellular secretome. The Educational Committee of the International Society for Extracellular Vesicles prepared two posters ("Basic aspects of extracellular vesicles" and "Clinical aspects of extracellular vesicles") to provide essential pieces of information on extracellular vesicles at glance for anyone not familiar with the field.

Entities: Chemical Disease Gene Species

Keywords: Extracellular vesicles (EVs); biogenesis; biomarker; biorepository; molecular composition; therapy

Year: 2018 PMID： 30533205 PMCID： PMC6282440 DOI： 10.1080/20013078.2018.1548234

Source DB: PubMed Journal: J Extracell Vesicles ISSN： 2001-3078

Basic and clinical aspects of extracellular vesicles

Since 2010, the scientific and clinical interest in extracellular vesicles (EVs) is growing exponentially. EVs are small, lipid membrane enclosed subcellular structures carrying biomolecules which are released by cells into their environment [1-3]. The term “EVs” is an umbrella term for all types of vesicles, including “exosomes” and “microparticles” or “microvesicles” [4]. This term is endorsed by the International Society on Extracellular Vesicles (ISEV; www.isev.org), a global scientific society founded in 2011), because at present no biochemical or (bio)physical distinction can be made between types of EVs generated by different biogenesis pathways [2]. Basic aspects of extracellular vesicles. Clinical aspects of extracellular vesicles The two posters by ISEV on “” and “” provide a brief introduction about EVs to students and (bio) medical healthcare professionals.

Basic aspects of extracellular vesicles (Figure 1)

All cells release EVs into their environment, and (bio)fluids such as conditioned culture medium and body fluids contain EVs. When EVs are visualized by electron microscopy (A and B are EM microphotographs provided by Rienk Nieuwland and Agnes Kittel, respectively), EVs appear as small, usually spherical particles surrounded by a phospholipid bilayer membrane. This membrane often contains proteins from the parental cell, thus enabling the identification of the cell of origin. In addition, EVs contain biomolecules originating from the parental cells, including RNA and DNA, metabolites and lipids [5]. Initially, EVs were often named after the cell type of origin, or after the organ in which they were discovered, such as dexosomes or prostasomes. Because this nomenclature was not only confusing but also resulted in development of parallel research fields lacking interaction, ISEV endorses the term “extracellular vesicles” as an umbrella term [Chttp://evpedia.info, 6]. Detailed analysis of the biochemical composition of EVs has shown that the overall composition of EVs differs from that of the releasing parental cells. This implies that cargo sorting mechanisms exits that affect the composition of EVs. Moreover, the biochemical composition depends on the “status” (resting, activated, etc.) of the parental cell. EVs can be released directly by budding from the plasma membrane, by secretion of prestored EVs in multi-vesicular bodies, by formation of apoptotic bodies as well as released from enveloped virus-infected cells (D). Due to all these variables, EVs are highly heterogeneous in size and composition [7-9]. EVs are not merely “innocent bystanders” but play important roles in physiology and pathology (E). In physiology, EVs contribute to homeostasis and promote host-defence mechanisms including haemostasis and inflammation [3], whereas in pathology EVs may contribute to disease development and progression, for example in cancer [10,11]. Because EVs are capable of delivering their proteins, lipid and RNA cargo to target (recipient) cells, EVs can regulate gene expression and consequently the phenotype and biological functions of the target cell. Thus, by exchanging information between cells, EVs contribute to intercellular communication. ISEV (F) developed a massive open online course on EVs that is freely available [Massive Online Open Course (MOOC) (G), http://coursera.org/learn/extracelllular-vesicles, 12], published minimal requirements for studies on EVs [MISEV, 13] (H). ISEV endorses a knowledge base that has been launched to monitor the quality of pre-analytical data reporting [http://evtrack.org, 14] (H). The official journal of ISEV is the Journal of Extracellular Vesicles (JEV) (I).

Clinical aspects of extracellular vesicles (Figure 2)

In general, EVs have a huge potential for diagnosis of disease, prognosis and monitoring of therapy [15]. Because EVs can be considered as naturally occurring autologous nanocarriers”, EVs can be loaded with drugs for local drug delivery (A). At present, standard operation procedures are being developed for routine collection, storage and handling of biofluids and body fluids such as urine, blood and breast milk to enable the comparison of measurements between patients and controls and to allow exchange of data between institutes and instruments, etc. (B). In most clinical studies, EV-containing biofluids will be collected in biorepositories. The pre-analytical conditions may differ between biofluids, but removal of cells and cell fragments is essential to circumvent contamination due fragmentation of cells during freeze thawing (C). Because all human (and animal) body fluids contain EVs, and because the cellular origin, composition and functions of EVs change in disease, the detailed analysis of EVs is thought to behold clinically relevant information. To get access to this information, however, most downstream applications require either isolation and/or concentration of EVs (D). Detection of (single) EVs and detailed insight into their biochemical composition by downstream methods such as proteomics requires a thorough understanding of the biochemical and (bio)physical limitations and possibilities of the various isolation, detection and characterization methods (E). In addition, the method of collection, handling and storage conditions of EV can alter the molecular composition of EV [16,17]. For more information, please visit the MOOC on EVs (F), the Journal of Extracellular Vesicles (JEV) (G) or contact the International Society for Extracellular Vesicles (H).

17 in total

Review 1. Classification, functions, and clinical relevance of extracellular vesicles.

Authors: Edwin van der Pol; Anita N Böing; Paul Harrison; Augueste Sturk; Rienk Nieuwland
Journal: Pharmacol Rev Date: 2012-06-21 Impact factor: 25.468

2. Proteomic comparison defines novel markers to characterize heterogeneous populations of extracellular vesicle subtypes.

Authors: Joanna Kowal; Guillaume Arras; Marina Colombo; Mabel Jouve; Jakob Paul Morath; Bjarke Primdal-Bengtson; Florent Dingli; Damarys Loew; Mercedes Tkach; Clotilde Théry
Journal: Proc Natl Acad Sci U S A Date: 2016-02-08 Impact factor: 11.205

3. Biological properties of extracellular vesicles and their physiological functions.

Authors: María Yáñez-Mó; Pia R-M Siljander; Zoraida Andreu; Apolonija Bedina Zavec; Francesc E Borràs; Edit I Buzas; Krisztina Buzas; Enriqueta Casal; Francesco Cappello; Joana Carvalho; Eva Colás; Anabela Cordeiro-da Silva; Stefano Fais; Juan M Falcon-Perez; Irene M Ghobrial; Bernd Giebel; Mario Gimona; Michael Graner; Ihsan Gursel; Mayda Gursel; Niels H H Heegaard; An Hendrix; Peter Kierulf; Katsutoshi Kokubun; Maja Kosanovic; Veronika Kralj-Iglic; Eva-Maria Krämer-Albers; Saara Laitinen; Cecilia Lässer; Thomas Lener; Erzsébet Ligeti; Aija Linē; Georg Lipps; Alicia Llorente; Jan Lötvall; Mateja Manček-Keber; Antonio Marcilla; Maria Mittelbrunn; Irina Nazarenko; Esther N M Nolte-'t Hoen; Tuula A Nyman; Lorraine O'Driscoll; Mireia Olivan; Carla Oliveira; Éva Pállinger; Hernando A Del Portillo; Jaume Reventós; Marina Rigau; Eva Rohde; Marei Sammar; Francisco Sánchez-Madrid; N Santarém; Katharina Schallmoser; Marie Stampe Ostenfeld; Willem Stoorvogel; Roman Stukelj; Susanne G Van der Grein; M Helena Vasconcelos; Marca H M Wauben; Olivier De Wever
Journal: J Extracell Vesicles Date: 2015-05-14

Review 4. Extracellular vesicle communication pathways as regulatory targets of oncogenic transformation.

Authors: Dongsic Choi; Tae Hoon Lee; Cristiana Spinelli; Shilpa Chennakrishnaiah; Esterina D'Asti; Janusz Rak
Journal: Semin Cell Dev Biol Date: 2017-01-08 Impact factor: 7.727

Review 5. Shedding light on the cell biology of extracellular vesicles.

Authors: Guillaume van Niel; Gisela D'Angelo; Graça Raposo
Journal: Nat Rev Mol Cell Biol Date: 2018-01-17 Impact factor: 94.444

Review 6. Methodological Guidelines to Study Extracellular Vesicles.

Authors: Frank A W Coumans; Alain R Brisson; Edit I Buzas; Françoise Dignat-George; Esther E E Drees; Samir El-Andaloussi; Costanza Emanueli; Aleksandra Gasecka; An Hendrix; Andrew F Hill; Romaric Lacroix; Yi Lee; Ton G van Leeuwen; Nigel Mackman; Imre Mäger; John P Nolan; Edwin van der Pol; D Michiel Pegtel; Susmita Sahoo; Pia R M Siljander; Guus Sturk; Olivier de Wever; Rienk Nieuwland
Journal: Circ Res Date: 2017-05-12 Impact factor: 17.367

7. Is your article EV-TRACKed?

Authors: Jan Van Deun; An Hendrix
Journal: J Extracell Vesicles Date: 2017-11-10

8. Updating the MISEV minimal requirements for extracellular vesicle studies: building bridges to reproducibility.

Authors: Kenneth W Witwer; Carolina Soekmadji; Andrew F Hill; Marca H Wauben; Edit I Buzás; Dolores Di Vizio; Juan M Falcon-Perez; Chris Gardiner; Fred Hochberg; Igor V Kurochkin; Jan Lötvall; Suresh Mathivanan; Rienk Nieuwland; Susmita Sahoo; Hidetoshi Tahara; Ana Claudia Torrecilhas; Alissa M Weaver; Hang Yin; Lei Zheng; Yong Song Gho; Peter Quesenberry; Clotilde Théry
Journal: J Extracell Vesicles Date: 2017-11-15

Review 9. Extracellular vesicles: the growth as diagnostics and therapeutics; a survey.

Authors: Sabrina Roy; Fred H Hochberg; Pamela S Jones
Journal: J Extracell Vesicles Date: 2018-02-26

10. Modulation of paracrine signaling by CD9 positive small extracellular vesicles mediates cellular growth of androgen deprived prostate cancer.

Authors: Carolina Soekmadji; James D Riches; Pamela J Russell; Jayde E Ruelcke; Stephen McPherson; Chenwei Wang; Chris M Hovens; Niall M Corcoran; Michelle M Hill; Colleen C Nelson
Journal: Oncotarget Date: 2016-08-08

8 in total

Review 1. Theragnostic Applications of Mammal and Plant-Derived Extracellular Vesicles: Latest Findings, Current Technologies, and Prospects.

Authors: Nada Basheir Ali; Ahmad Faizal Abdull Razis; Der Jiun Ooi; Kim Wei Chan; Norsharina Ismail; Jhi Biau Foo
Journal: Molecules Date: 2022-06-20 Impact factor: 4.927

2. Extracellular Vesicles Derived from Senescent Fibroblasts Attenuate the Dermal Effect on Keratinocyte Differentiation.

Authors: Eun-Jeong Choi; In Sup Kil; Eun-Gyung Cho
Journal: Int J Mol Sci Date: 2020-02-04 Impact factor: 5.923

Review 3. Stem/progenitor cell in kidney: characteristics, homing, coordination, and maintenance.

Authors: Jiewu Huang; Yaozhong Kong; Chao Xie; Lili Zhou
Journal: Stem Cell Res Ther Date: 2021-03-20 Impact factor: 6.832

4. Announcing the ISEV2020 special achievement award recipients: Andrew Hill and Edit Buzás; and the recipient of the ISEV2020 special education award: Carolina Soekmadji.

Authors: Kenneth W Witwer; Lucia R Languino; Alissa M Weaver; Marca H Wauben
Journal: J Extracell Vesicles Date: 2020-11-05

8. [Gly14]-Humanin Ameliorates High Glucose-Induced Apoptosis by Inhibiting the Expression of MicroRNA-155 in Endothelial Microparticles.

Authors: Meng-Yuan Shen; Miao Wang; Zhihua Liu; Shurong Wang; Ying Xie
Journal: Diabetes Metab Syndr Obes Date: 2021-05-24 Impact factor: 3.168