A CRISPR-Cas9-based reporter system for single-cell detection of extracellular vesicle-mediated functional transfer of RNA

Jong, Olivier G. de; Murphy, Daniel E.; Mäger, Imre; Willms, Eduard; Garcia-Guerra, Antonio; Gitz-Francois, Jerney J.; Lefferts, J.W.; Gupta, Dhanu; Steenbeek, Sander Christiaan; Rheenen, Jacco van; Andaloussi, Samir El; Schiffelers, Raymond M.; Wood, Matthew J.; Vader, Pieter

doi:10.1038/s41467-020-14977-8

Cited by 116 publications

(135 citation statements)

References 56 publications

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“…They cannot be removed sufficiently by differential centrifugation (Auber et al ., 2019), and while high‐resolution density gradients can help separate out some nonvesicle particles (Jeppesen et al ., 2019), other particles, such as miRNA‐associated lipoprotein complexes, have been found to co‐purify with vesicle‐rich fractions (Sodar et al ., 2016). Because many extracellular RNAs are associated with protein complexes, RNase treatment is usually only effective following a proteinase treatment (Arroyo et al ., 2011; Shurtleff et al ., 2017); thus, RNase protection assays should be performed after protease treatment (de Jong et al ., 2020). Validating EV RNA cargo requires multiple controls and considerations, as detailed in Box 3.…”

Section: Extracellular Vesicles and Rna Transportmentioning

confidence: 99%

Growing pains: addressing the pitfalls of plant extracellular vesicle research

Rutter

Innes

2020

New Phytologist

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Summary Extracellular vesicles (EVs) are small, membrane‐enclosed compartments that mediate the intercellular transport of proteins and small RNAs. In plants, EVs are thought to play a prominent role in immune responses and are being championed as the long‐sought‐after mechanism for host‐induced gene silencing. However, parallel research on mammalian EVs is raising concerns about potential pitfalls faced by all EV researchers that will need to be addressed in order to convincingly establish that EVs are the primary mediators of small RNA transfer between organisms. Here we discuss these pitfalls in the context of plant EV research, with a focus on experimental approaches required to distinguish bona fide EV cargo from merely co‐purifying contaminants.

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Section: Extracellular Vesicles and Rna Transportmentioning

confidence: 99%

Growing pains: addressing the pitfalls of plant extracellular vesicle research

Rutter

Innes

2020

New Phytologist

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“…Genome-editing factors, packaged in engineered CRISPR/Cas9 complexes, can be enclosed in extracellular vesicles (EVs), for delivery to specific target cells [ 86 , 87 ]. EVs are composed of cellular constituents such as lipids, proteins, RNA, and DNA [ 86 , 88 ].…”

Section: Extracellular Vesiclesmentioning

confidence: 99%

“…EVs are composed of cellular constituents such as lipids, proteins, RNA, and DNA [ 86 , 88 ]. EVs may cross the blood–brain barrier, target cells in vivo, and protect their components from degradation in the circulatory system [ 87 , 89 ]. Their function is dependent upon their origin, and EVs derived from MSCs could have the potential to deliver contents to OA cells [ 90 , 91 , 92 , 93 ], as shown in Figure 3 [ 85 , 94 , 95 ].…”

Section: Extracellular Vesiclesmentioning

confidence: 99%

Emerging Gene-Editing Modalities for Osteoarthritis

Tanikella

Hardy

Frahs

et al. 2020

IJMS

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Osteoarthritis (OA) is a pathological degenerative condition of the joints that is widely prevalent worldwide, resulting in significant pain, disability, and impaired quality of life. The diverse etiology and pathogenesis of OA can explain the paucity of viable preventive and disease-modifying strategies to counter it. Advances in genome-editing techniques may improve disease-modifying solutions by addressing inherited predisposing risk factors and the activity of inflammatory modulators. Recent progress on technologies such as CRISPR/Cas9 and cell-based genome-editing therapies targeting the genetic and epigenetic alternations in OA offer promising avenues for early diagnosis and the development of personalized therapies. The purpose of this literature review was to concisely summarize the genome-editing options against chronic degenerative joint conditions such as OA with a focus on the more recently emerging modalities, especially CRISPR/Cas9. Future advancements in novel genome-editing therapies may improve the efficacy of such targeted treatments.

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“…[13] Interestingly, the relevance of EVs is witnessed by their conservation during evolution from bacteria to superior eukaryotes, such as human and plants, and their ability to mediate even the "inter-kingdom" communication. [24] Several biomolecules may be carried within the lumen of EVs, such as DNA (both mitochondrial and genomic), [25,26] RNA (including mRNA, miRNA, siRNA, and lncRNA), [27][28][29][30] lipids and functional proteins (such as active enzymes). [23] These cargoes are protected from degradation by proteases and nucleases, commonly present in the extracellular environment, allowing for an efficient delivery of active biomolecules to target cells.…”

Section: Introductionmentioning

confidence: 99%

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

Leggio

Arrabito

Ferrara

et al. 2020

Adv Healthcare Materials

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Naturally occurring extracellular vesicles and artificially made vesicles represent important tools in nanomedicine for the efficient delivery of biomolecules and drugs. Since its first appearance in the literature 50 years ago, the research on vesicles is progressing at a fast pace, with the main goal of developing carriers able to protect cargoes from degradation, as well as to deliver them in a time‐ and space‐controlled fashion. While natural occurring vesicles have the advantage of being fully compatible with their host, artificial vesicles can be easily synthetized and functionalized according to the target to reach. Research is striving to merge the advantages of natural and artificial vesicles, in order to provide a new generation of highly performing vesicles, which would improve the therapeutic index of transported molecules. This progress report summarizes current manufacturing techniques used to produce both natural and artificial vesicles, exploring the promises and pitfalls of the different production processes. Finally, pros and cons of natural versus artificial vesicles are discussed and compared, with special regard toward the current applications of both kinds of vesicles in the healthcare field.

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A CRISPR-Cas9-based reporter system for single-cell detection of extracellular vesicle-mediated functional transfer of RNA

Cited by 116 publications

References 56 publications

Growing pains: addressing the pitfalls of plant extracellular vesicle research

Growing pains: addressing the pitfalls of plant extracellular vesicle research

Emerging Gene-Editing Modalities for Osteoarthritis

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

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