RNA in Exosomes and Extracellular-Vesicles (EVs)
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The EV and exosomal
RNA
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Obstacles and opportunities in the
functional analysis of extracellular vesicle RNA - an ISEV position
paper.
Mateescu B, Kowal
EJ, van Balkom BW, Bartel S, Bhattacharyya SN, Buzás EI, Buck
AH, de Candia P, Chow FW, Das S, Driedonks TA, Fernández-Messina
L, Haderk F, Hill AF, Jones JC, Van Keuren-Jensen KR, Lai CP,
Lässer C, Liegro ID, Lunavat TR, Lorenowicz MJ, Maas SL,
Mäger I, Mittelbrunn M, Momma S, Mukherjee K, Nawaz M, Pegtel DM,
Pfaffl MW, Schiffelers RM, Tahara H, Théry C, Tosar JP, Wauben
MH, Witwer KW, Nolte-'t Hoen EN
J Extracell Vesicles. 2017 6(1): 1286095 --
eCollection 2017
The release of
RNA-containing extracellular vesicles (EV) into the extracellular
milieu has been demonstrated in a multitude of different in vitro cell
systems and in a variety of body fluids. RNA-containing EV are in the
limelight for their capacity to communicate genetically encoded
messages to other cells, their suitability as candidate biomarkers for
diseases, and their use as therapeutic agents. Although EV-RNA has
attracted enormous interest from basic researchers, clinicians, and
industry, we currently have limited knowledge on which mechanisms drive
and regulate RNA incorporation into EV and on how RNA-encoded messages
affect signalling processes in EV-targeted cells. Moreover, EV-RNA
research faces various technical challenges, such as standardisation of
EV isolation methods, optimisation of methodologies to isolate and
characterise minute quantities of RNA found in EV, and development of
approaches to demonstrate functional transfer of EV-RNA in vivo. These
topics were discussed at the 2015 EV-RNA workshop of the International
Society for Extracellular Vesicles. This position paper was written by
the participants of the workshop not only to give an overview of the
current state of knowledge in the field, but also to clarify that our
incomplete knowledge - of the nature of EV(-RNA)s and of how to
effectively and reliably study them - currently prohibits the
implementation of gold standards in EV-RNA research. In addition, this
paper creates awareness of possibilities and limitations of currently
used strategies to investigate EV-RNA and calls for caution in
interpretation of the obtained data.
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Summary of the ISEV workshop on
extracellular vesicles as disease biomarkers;
Meeting Report --
held in Birmingham, UK, during December 2017
Aled Clayton,
Dominik Buschmann, J. Brian Byrd, David R. F. Carter, Lesley Cheng,
Carolyn Compton, George Daaboul, Andrew Devitt, Juan Manuel
Falcon-Perez, Chris Gardiner, Dakota Gustafson, Paul Harrison, Clemens
Helmbrecht, An Hendrix, Andrew Hill, Andrew Hoffman, Jennifer C. Jones,
Raghu Kalluri, Ji Yoon Kang, Benedikt Kirchner, Cecilia Lässer,
Charlotte Lawson, Metka Lenassi, Carina Levin, Alicia Llorente, Elena
S. Martens-Uzunova, Andreas Möller, Luca Musante, Takahiro Ochiya,
Ryan C Pink, Hidetoshi Tahara, Marca H. M. Wauben, Jason P. Webber,
Joshua A. Welsh, Kenneth W. Witwer, Hang Yin & Rienk Nieuwland
Journal of Extracellular Vesicles 2018 (7)1
This report
summarises the presentations and activities of the ISEV Workshop on
extracellular vesicle biomarkers held in Birmingham, UK during December
2017. Among the key messages was broad agreement about the importance
of biospecimen science. Much greater attention needs to be paid towards
the provenance of collected samples. The workshop also highlighted
clear gaps in our knowledge about pre-analytical factors that alter
extracellular vesicles (EVs). The future utility of certified standards
for credentialing of instruments and software, to analyse EV and for
tracking the influence of isolation steps on the structure and content
of EVs were also discussed. Several example studies were presented,
demonstrating the potential utility for EVs in disease diagnosis,
prognosis, longitudinal serial testing and stratification of patients.
The conclusion of the workshop was that more effort focused on
pre-analytical issues and benchmarking of isolation methods is needed
to strengthen collaborations and advance more effective biomarkers.
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Two distinct extracellular RNA signatures
released by a single cell type identified by microarray and
next-generation sequencing.
Lässer C, Shelke GV, Yeri A, Kim DK, Crescitelli R, Raimondo S,
Sjöstrand M, Gho YS, Van Keuren Jensen K, Lötvall J
RNA Biol. 2017 14(1): 58-72
Cells secrete
extracellular RNA (exRNA) to their surrounding environment and exRNA
has been found in many body fluids such as blood, breast milk and
cerebrospinal fluid. However, there are conflicting results regarding
the nature of exRNA. Here, we have separated 2 distinct exRNA profiles
released by mast cells, here termed high-density (HD) and low-density
(LD) exRNA. The exRNA in both fractions was characterized by microarray
and next-generation sequencing. Both exRNA fractions contained mRNA and
miRNA, and the mRNAs in the LD exRNA correlated closely with the
cellular mRNA, whereas the HD mRNA did not. Furthermore, the HD exRNA
was enriched in lincRNA, antisense RNA, vault RNA, snoRNA, and snRNA
with little or no evidence of full-length 18S and 28S rRNA. The LD
exRNA was enriched in mitochondrial rRNA, mitochondrial tRNA, tRNA,
piRNA, Y RNA, and full-length 18S and 28S rRNA. The proteomes of the HD
and LD exRNA-containing fractions were determined with LC-MS/MS and
analyzed with Gene Ontology term finder, which showed that both
proteomes were associated with the term extracellular vesicles and
electron microscopy suggests that at least a part of the exRNA is
associated with exosome-like extracellular vesicles. Additionally, the
proteins in the HD fractions tended to be associated with the nucleus
and ribosomes, whereas the LD fraction proteome tended to be associated
with the mitochondrion. We show that the 2 exRNA signatures released by
a single cell type can be separated by floatation on a density
gradient. These results show that cells can release multiple types of
exRNA with substantial differences in RNA species content. This is
important for any future studies determining the nature and function of
exRNA released from different cells under different conditions.
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Evaluation of serum extracellular vesicle
isolation methods for profiling miRNAs by next-generation sequencing.
Buschmann D,
Kirchner B, Hermann S, Märte M, Wurmser C, Brandes F, Kotschote S,
Bonin M, Steinlein OK, Pfaffl MW, Schelling G, Reithmair M
J Extracell Vesicles. 2018 7(1): 1481321 --
eCollection 2018
Extracellular
vesicles (EVs) are intercellular communicators with key functions in
physiological and pathological processes and have recently garnered
interest because of their diagnostic and therapeutic potential. The
past decade has brought about the development and commercialization of
a wide array of methods to isolate EVs from serum. Which subpopulations
of EVs are captured strongly depends on the isolation method, which in
turn determines how suitable resulting samples are for various
downstream applications. To help clinicians and scientists choose the
most appropriate approach for their experiments, isolation methods need
to be comparatively characterized. Few attempts have been made to
comprehensively analyse vesicular microRNAs (miRNAs) in patient
biofluids for biomarker studies. To address this discrepancy, we set
out to benchmark the performance of several isolation principles for
serum EVs in healthy individuals and critically ill patients. Here, we
compared five different methods of EV isolation in combination with two
RNA extraction methods regarding their suitability for biomarker
discovery-focused miRNA sequencing as well as biological
characteristics of captured vesicles. Our findings reveal striking
method-specific differences in both the properties of isolated vesicles
and the ability of associated miRNAs to serve in biomarker research.
While isolation by precipitation and membrane affinity was highly
suitable for miRNA-based biomarker discovery, methods based on
size-exclusion chromatography failed to separate patients from healthy
volunteers. Isolated vesicles differed in size, quantity, purity and
composition, indicating that each method captured distinctive
populations of EVs as well as additional contaminants. Even though the
focus of this work was on transcriptomic profiling of EV-miRNAs, our
insights also apply to additional areas of research. We provide
guidance for navigating the multitude of EV isolation methods available
today and help researchers and clinicians make an informed choice about
which strategy to use for experiments involving critically ill patients.
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The impact of disparate isolation methods
for extracellular vesicles on downstream RNA profiling.
Van Deun J, Mestdagh P, Sormunen R, Cocquyt V, Vermaelen K,
Vandesompele J, Bracke M, De Wever O, Hendrix A.
J Extracell Vesicles. 2014 Sep 18;3 -- eCollection 2014.
Despite an
enormous interest in the role of extracellular vesicles,
including exosomes, in cancer and their use as biomarkers for
diagnosis, prognosis, drug response and recurrence, there is no
consensus on dependable isolation protocols. We provide a comparative
evaluation of 4 exosome isolation protocols for their usability, yield
and purity, and their impact on downstream omics approaches for
biomarker discovery. OptiPrep density gradient centrifugation
outperforms ultracentrifugation and ExoQuick and Total Exosome
Isolation precipitation in terms of purity, as illustrated by the
highest number of CD63-positive nanovesicles, the highest enrichment in
exosomal marker proteins and a lack of contaminating proteins such as
extracellular Argonaute-2 complexes. The purest exosome fractions
reveal a unique mRNA profile enriched for translation, ribosome,
mitochondrion and nuclear lumen function. Our results demonstrate that
implementation of high purification techniques is a prerequisite to
obtain reliable omics data and identify exosome-specific functions and
biomarkers.
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Importance of RNA isolation methods for
analysis of exosomal RNA -- evaluation of different methods.
Eldh M, Lötvall J, Malmhäll C, Ekström K.
Mol Immunol. 2012 Apr;50(4): 278-86.
Exosomes are small
RNA containing vesicles of endocytic origin, which can take part in
cell-to-cell communication partly by the transfer of exosomal RNA
between cells. Exosomes are released by many cells and can also be
found in several biological fluids including blood plasma and breast
milk. Exosomes differ compared to their donor cells not only in size
but also in RNA, protein and lipid composition. The aim of the current
study was to determine the optimal RNA extraction method for analysis
of exosomal RNA, to support future studies determining the biological
roles of the exosomal RNA. Different methods were used to extract
exosomal and cellular RNA. All methods evaluated extracted high quality
and purity RNA as determined by RNA integrity number (RIN) and OD
values for cellular RNA using capillary electrophoresis and
spectrophotometer. Interestingly, the exosomal RNA yield differed
substantially between the different RNA isolation methods. There was
also a difference in the exosomal RNA patterns in the
electropherograms, indicating that the tested methods extract exosomal
RNA with different size distribution. A pure column based approach
resulted in the highest RNA yield and the broadest RNA size
distribution, whereas phenol and combined phenol and column based
approaches lost primarily large RNAs. Moreover, the use of phenol and
combined techniques resulted in reduced yield of exosomal RNA, with a
more narrow size distribution pattern resulting in an enrichment of
small RNA including microRNA. In conclusion, the current study presents
a unique comparison of seven different methods for extraction of
exosomal RNA. As the different isolation methods give extensive
variation in exosomal RNA yield and patterns, it is crucial to select
an isolation approach depending on the research question at hand.
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Selective release of circRNAs in
platelet-derived extracellular vesicles.
Preußer C, Hung LH, Schneider T, Schreiner S, Hardt M, Moebus A,
Santoso S, Bindereif A
J Extracell Vesicles. 2018 Jan 15;7(1):1424473
Circular RNAs
(circRNAs) are a novel class of noncoding RNAs present in all
eukaryotic cells investigated so far and generated by a special mode of
alternative splicing of pre-mRNAs. Thereby, single exons, or multiple
adjacent and spliced exons, are released in a circular form. CircRNAs
are cell-type specifically expressed, are unusually stable, and can be
found in various body fluids such as blood and saliva. Here we analysed
circRNAs and the corresponding linear splice isoforms from human
platelets, where circRNAs are particularly abundant, compared with
other hematopoietic cell types. In addition, we isolated extracellular
vesicles from purified and in vitro activated human platelets, using
density-gradient centrifugation, followed by RNA-seq analysis for
circRNA detection. We could demonstrate that circRNAs are packaged and
released within both types of vesicles (microvesicles and exosomes)
derived from platelets. Interestingly, we observed a selective release
of circRNAs into the vesicles, suggesting a specific sorting mechanism.
In sum, circRNAs represent yet another class of extracellular RNAs that
circulate in the body and may be involved in signalling pathways. Since
platelets are essential for central physiological processes such as
haemostasis, wound healing, inflammation and cancer metastasis, these
findings should greatly extend the potential of circRNAs as prognostic
and diagnostic biomarkers.
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A comprehensive method for identification
of suitable reference genes in extracellular vesicles.
Gouin K, Peck K, Antes T, Johnson JL, Li C, Vaturi SD, Middleton R, de
Couto G, Walravens AS, Rodriguez-Borlado L, Smith RR, Marbán L,
Marbán E, Ibrahim AG
J Extracell Vesicles. 2017 6(1): 1347019 -- eCollection 2017
Reverse
transcription-quantitative polymerase chain reaction (RT-qPCR) is one
of the most sensitive, economical and widely used methods for
evaluating gene expression. However, the utility of this method
continues to be undermined by a number of challenges including
normalization using appropriate reference genes. The need to develop
tailored and effective strategies is further underscored by the
burgeoning field of extracellular vesicle (EV) biology. EVs contain
unique signatures of small RNAs including microRNAs (miRs). In this
study we develop and validate a comprehensive strategy for identifying
highly stable reference genes in a therapeutically relevant cell type,
cardiosphere-derived cells. Data were analysed using the four major
approaches for reference gene evaluation: NormFinder, GeNorm,
BestKeeper and the Delta Ct method. The weighted geometric mean of all
of these methods was obtained for the final ranking. Analysis of RNA
sequencing identified miR-101-3p, miR-23a-3p and a previously
identified EV reference gene, miR-26a-5p. Analysis of a chip-based
method (NanoString) identified miR-23a, miR-217 and miR-379 as stable
candidates. RT-qPCR validation revealed that the mean of miR-23a-3p,
miR-101-3p and miR-26a-5p was the most stable normalization strategy.
Here, we demonstrate that a comprehensive approach of a diverse data
set of conditions using multiple algorithms reliably identifies stable
reference genes which will increase the utility of gene expression
evaluation of therapeutically relevant EVs.
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Exosomes
provide a protective and enriched source of miRNA for biomarker
profiling compared to intracellular and cell-free blood.
Cheng L, Sharples RA, Scicluna BJ, Hill AF
J Extracell Vesicles. 2014 Mar 26;3 -- eCollection 2014
INTRODUCTION:
microRNA (miRNA)
are small non-coding RNA species that are transcriptionally processed
in the host cell and released extracellularly into the bloodstream.
Normally involved in post-transcriptional gene silencing, the
deregulation of miRNA has been shown to influence pathogenesis of a
number of diseases.
BACKGROUND: Next-generation
deep sequencing (NGS) has provided the ability to profile miRNA in
biological fluids making this approach a viable screening tool to
detect miRNA biomarkers. However, collection and handling procedures of
blood needs to be greatly improved for miRNA analysis in order to
reliably detect differences between healthy and disease patients.
Furthermore, ribonucleases present in blood can degrade RNA upon
collection rendering extracellular miRNA at risk of degradation. These
factors have consequently decreased sensitivity and specificity of
miRNA biomarker assays.
METHODS: Here,
we use NGS to
profile miRNA in various blood components and identify differences in
profiles within peripheral blood compared to cell-free plasma or serum
and extracellular vesicles known as exosomes. We also analyse and
compare the miRNA content in exosomes prepared by ultracentrifugation
methods and commercial exosome isolation kits including treating
samples with RNaseA.
CONCLUSION:
This study
demonstrates that exosomal RNA is protected by RNaseA treatment and
that exosomes provide a consistent source of miRNA for disease
biomarker detection. |
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Cellular and extracellular miRNAs are
blood-compartment-specific diagnostic targets in sepsis.
Reithmair M, Buschmann D, Märte M, Kirchner B, Hagl D, Kaufmann I,
Pfob M, Chouker A, Steinlein OK, Pfaffl MW, Schelling G
J Cell Mol Med. 2017 21(10): 2403-2411
Septic shock is a
common medical condition with a mortality approaching 50% where early
diagnosis and treatment are of particular importance for patient
survival. Novel biomarkers that serve as prompt indicators of sepsis
are urgently needed. High-throughput technologies assessing circulating
microRNAs represent an important tool for biomarker identification, but
the blood-compartment specificity of these miRNAs has not yet been
investigated. We characterized miRNA profiles from serum exosomes,
total serum and blood cells (leukocytes, erythrocytes, platelets) of
sepsis patients by next-generation sequencing and RT-qPCR (n = 3
× 22) and established differences in miRNA expression between
blood compartments. In silico analysis was used to identify
compartment-specific signalling functions of differentially regulated
miRNAs in sepsis-relevant pathways. In septic shock, a total of 77 and
103 miRNAs were down- and up-regulated, respectively. A majority of
these regulated miRNAs (14 in serum, 32 in exosomes and 73 in blood
cells) had not been previously associated with sepsis. We found a
distinctly compartment-specific regulation of miRNAs between sepsis
patients and healthy volunteers. Blood cellular miR-199b-5p was
identified as a potential early indicator for sepsis and septic shock.
miR-125b-5p and miR-26b-5p were uniquely regulated in exosomes and
serum, respectively, while one miRNA (miR-27b-3p) was present in all
three compartments. The expression of sepsis-associated miRNAs is
compartment-specific. Exosome-derived miRNAs contribute significant
information regarding sepsis diagnosis and survival prediction and
could serve as newly identified targets for the development of novel
sepsis biomarkers.
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Toward reliable biomarker signatures in the
age of liquid biopsies - how to standardize the small RNA-Seq workflow.
Buschmann D, Haberberger A, Kirchner B, Spornraft M, Riedmaier I,
Schelling G, Pfaffl MW
Nucleic Acids Res. 2016 44(13): 5995-6018
Small RNA-Seq has
emerged as a powerful tool in transcriptomics, gene expression
profiling and biomarker discovery. Sequencing cell-free nucleic acids,
particularly microRNA (miRNA), from liquid biopsies additionally
provides exciting possibilities for molecular diagnostics, and might
help establish disease-specific biomarker signatures. The complexity of
the small RNA-Seq workflow, however, bears challenges and biases that
researchers need to be aware of in order to generate high-quality data.
Rigorous standardization and extensive validation are required to
guarantee reliability, reproducibility and comparability of research
findings. Hypotheses based on flawed experimental conditions can be
inconsistent and even misleading. Comparable to the well-established
MIQE guidelines for qPCR experiments, this work aims at establishing
guidelines for experimental design and pre-analytical sample
processing, standardization of library preparation and sequencing
reactions, as well as facilitating data analysis. We highlight
bottlenecks in small RNA-Seq experiments, point out the importance of
stringent quality control and validation, and provide a primer for
differential expression analysis and biomarker discovery. Following our
recommendations will encourage better sequencing practice, increase
experimental transparency and lead to more reproducible small RNA-Seq
results. This will ultimately enhance the validity of biomarker
signatures, and allow reliable and robust clinical predictions.
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Exosomes -- A Rising Star in Failing Hearts.
Jun-Yan Xu, Gui-Hao Chen and Yue-Jin Yang
Front Physiol. 2017 (8): 494
Although exosomes
were previously recognized as a mechanism for discharging useless
cellular components, growing evidence has elucidated their roles in
conveying information between cells. They contribute to cell–cell
communication by carrying nucleic acids, proteins and lipids that can,
in turn, regulate behavior of the target cells. Recent research
suggested that exosomes extensively participate in progression of
diverse cardiovascular diseases (CVDs), such as myocardial infarction,
cardiomyopathy, pulmonary arterial hypertension and others. Here, we
summarize effects of exosome-derived molecules (mainly microRNAs and
proteins) on cardiac function, to examine their potential applications
as biomarkers or therapeutics in CVDs.
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The majority of microRNAs detectable in
serum and saliva is concentrated in exosomes.
Gallo A, Tandon M, Alevizos I, Illei GG
PLoS One. 2012; 7(3): e30679
There is an
increasing interest in using microRNAs (miRNA) as biomarkers in
autoimmune diseases. They are easily accessible in many body fluids but
it is controversial if they are circulating freely or are encapsulated
in microvesicles, particularly exosomes. We investigated if the
majority of miRNas in serum and saliva are free-circulating or
concentrated in exosomes. Exosomes were isolated by ultracentrifugation
from fresh and frozen human serum and saliva. The amount of selected
miRNAs extracted from the exosomal pellet and the exosome-depleted
serum and saliva was compared by quantitative RT-PCR. Some miRNAs
tested are ubiquitously expressed, others were previously reported as
biomarkers. We included miRNAs previously reported to be free
circulating and some thought to be exosome specific. The purity of
exosome fraction was confirmed by electronmicroscopy and western blot.
The concentration of miRNAs was consistently higher in the exosome
pellet compared to the exosome-depleted supernatant. We obtained the
same results using an equal volume or equal amount of total RNA as
input of the RT-qPCR. The concentration of miRNA in whole,
unfractionated serum, was between the exosomal pellet and the
exosome-depleted supernatant. Selected miRNAs, which were detectable in
exosomes, were undetectable in whole serum and the exosome-depleted
supernantant. Exosome isolation improves the sensitivity of miRNA
amplification from human biologic fluids. Exosomal miRNA should be the
starting point for early biomarker studies to reduce the probability of
false negative results involving low abundance miRNAs that may be
missed by using unfractionated serum or saliva.
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http://evtrack.org
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EV-TRACK -- transparent
reporting and centralizing knowledge in extracellular vesicle research.
EV-TRACK Consortium, Van Deun J, Mestdagh P, Agostinis P, ... and much
more, Vandesompele J, Hendrix A
Nat Methods. 2017 14(3): 228-232
We argue
that the field of extracellular vesicle (EV) biology needs more
transparent reporting to facilitate interpretation and replication of
experiments. To achieve this, we describe EV-TRACK, a crowdsourcing
knowledgebase (http://evtrack.org) that
centralizes EV biology and methodology with the goal of stimulating
authors, reviewers, editors and funders to put experimental guidelines
into practice.
Is your article EV-TRACKed?
Van Deun J, Hendrix A, and the EV-TRACK consortium
J Extracell Vesicles. 2017 Nov 10;6(1): 1379835 -- eCollection 2017
The EV-TRACK knowledgebase is developed to cope with the need for
transparency and rigour to increase reproducibility and facilitate
standardization of extracellular vesicle (EV) research. The
knowledgebase includes a checklist for authors and editors intended to
improve the transparency of methodological aspects of EV experiments,
allows queries and meta-analysis of EV experiments and keeps track of
the current state of the art. Widespread implementation by the EV
research community is key to its success.
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Distinct RNA profiles in subpopulations of
extracellular vesicles -- apoptotic bodies, microvesicles and
exosomes.
Crescitelli R, Lässer C, Szabó TG, Kittel A, Eldh M,
Dianzani I, Buzás EI, Lötvall J
J Extracell Vesicles. 2013 2 -- eCollection 2013.
INTRODUCTION: In
recent years, there has been an exponential increase
in the number of studies aiming to understand the biology of exosomes,
as well as other extracellular vesicles. However, classification of
membrane vesicles and the appropriate protocols for their isolation are
still under intense discussion and investigation. When isolating
vesicles, it is crucial to use systems that are able to separate them,
to avoid cross-contamination.
METHOD: EVS RELEASED FROM THREE DIFFERENT KINDS OF
CELL LINES: HMC-1,
TF-1 and BV-2 were isolated using two centrifugation-based protocols.
In protocol 1, apoptotic bodies were collected at 2,000×g,
followed by filtering the supernatant through 0.8 µm pores and
pelleting of microvesicles at 12,200×g. In protocol 2, apoptotic
bodies and microvesicles were collected together at 16,500×g,
followed by filtering of the supernatant through 0.2 µm pores and
pelleting of exosomes at 120,000×g. Extracellular vesicles were
analyzed by transmission electron microscopy, flow cytometry and the
RNA profiles were investigated using a Bioanalyzer(®).
RESULTS: RNA profiles showed that ribosomal RNA was
primary detectable
in apoptotic bodies and smaller RNAs without prominent ribosomal RNA
peaks in exosomes. In contrast, microvesicles contained little or no
RNA except for microvesicles collected from TF-1 cell cultures. The
different vesicle pellets showed highly different distribution of size,
shape and electron density with typical apoptotic body, microvesicle
and exosome characteristics when analyzed by transmission electron
microscopy. Flow cytometry revealed the presence of CD63 and CD81 in
all vesicles investigated, as well as CD9 except in the TF-1-derived
vesicles, as these cells do not express CD9.
CONCLUSIONS: Our results demonstrate that
centrifugation-based
protocols are simple and fast systems to distinguish subpopulations of
extracellular vesicles. Different vesicles show different RNA profiles
and morphological characteristics, but they are indistinguishable using
CD63-coated beads for flow cytometry analysis.
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Quantitative and stoichiometric analysis of
the microRNA content of exosomes.
Chevillet JR, Kang Q, Ruf IK, Briggs HA, Vojtech LN, Hughes SM, Cheng
HH, Arroyo JD, Meredith EK, Gallichotte EN, Pogosova-Agadjanyan EL,
Morrissey C, Stirewalt DL, Hladik F, Yu EY, Higano CS, Tewari M
Proc Natl Acad Sci U S A. 2014 111(41): 14888-14893
Exosomes have been
proposed as vehicles for microRNA (miRNA) -based
intercellular communication and a source of miRNA biomarkers in bodily
fluids. Although exosome preparations contain miRNAs, a quantitative
analysis of their abundance and stoichiometry is lacking. In the course
of studying cancer-associated extracellular miRNAs in patient blood
samples, we found that exosome fractions contained a small minority of
the miRNA content of plasma. This low yield prompted us to perform a
more quantitative assessment of the relationship between miRNAs and
exosomes using a stoichiometric approach. We quantified both the number
of exosomes and the number of miRNA molecules in replicate samples that
were isolated from five diverse sources (i.e., plasma, seminal fluid,
dendritic cells, mast cells, and ovarian cancer cells). Regardless of
the source, on average, there was far less than one molecule of a given
miRNA per exosome, even for the most abundant miRNAs in exosome
preparations (mean ± SD across six exosome sources: 0.00825
± 0.02 miRNA molecules/exosome). Thus, if miRNAs were
distributed homogenously across the exosome population, on average,
over 100 exosomes would need to be examined to observe one copy of a
given abundant miRNA. This stoichiometry of miRNAs and exosomes
suggests that most individual exosomes in standard preparations do not
carry biologically significant numbers of miRNAs and are, therefore,
individually unlikely to be functional as vehicles for miRNA-based
communication. We propose revised models to reconcile the
exosome-mediated, miRNA-based intercellular communication hypothesis
with the observed stoichiometry of miRNAs associated with exosomes.
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The microRNA spectrum in 12 body fluids.
Weber JA, Baxter DH, Zhang S, Huang DY, Huang KH, Lee MJ, Galas DJ,
Wang K.
Clin Chem. 2010 56(11): 1733-1741
BACKGROUND:
MicroRNAs (miRNAs) are small, noncoding RNAs that play an
important role in regulating various biological processes through their
interaction with cellular messenger RNAs. Extracellular miRNAs in
serum, plasma, saliva, and urine have recently been shown to be
associated with various pathological conditions including cancer.
METHODS: With the goal of assessing the distribution
of miRNAs and
demonstrating the potential use of miRNAs as biomarkers, we examined
the presence of miRNAs in 12 human body fluids and urine samples from
women in different stages of pregnancy or patients with different
urothelial cancers. Using quantitative PCR, we conducted a global
survey of the miRNA distribution in these fluids.
RESULTS: miRNAs were present in all fluids tested
and showed distinct
compositions in different fluid types. Several of the highly abundant
miRNAs in these fluids were common among multiple fluid types, and some
of the miRNAs were enriched in specific fluids. We also observed
distinct miRNA patterns in the urine samples obtained from individuals
with different physiopathological conditions.
CONCLUSIONS: MicroRNAs are ubiquitous in all the
body fluid types
tested. Fluid type-specific miRNAs may have functional roles associated
with the surrounding tissues. In addition, the changes in miRNA spectra
observed in the urine samples from patients with different urothelial
conditions demonstrates the potential for using concentrations of
specific miRNAs in body fluids as biomarkers for detecting and
monitoring various physiopathological conditions.
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Analysis of extracellular RNA in
cerebrospinal fluid.
Saugstad JA, Lusardi TA, Van Keuren-Jensen KR, Phillips JI, Lind B,
Harrington CA, McFarland TJ, Courtright AL, Reiman RA, Yeri AS, Kalani
MYS, Adelson PD, Arango J, Nolan JP, Duggan E, Messer K, Akers JC,
Galasko DR, Quinn JF, Carter BS, Hochberg FH
J Extracell Vesicles. 2017 6(1): 1317577
We examined the
extracellular vesicle (EV) and RNA composition of pooled normal
cerebrospinal fluid (CSF) samples and CSF from five major neurological
disorders: Alzheimer's disease (AD), Parkinson's disease (PD),
low-grade glioma (LGG), glioblastoma multiforme (GBM), and subarachnoid
haemorrhage (SAH), representing neurodegenerative disease, cancer, and
severe acute brain injury. We evaluated: (I) size and quantity of EVs
by nanoparticle tracking analysis (NTA) and vesicle flow cytometry
(VFC), (II) RNA yield and purity using four RNA isolation kits, (III)
replication of RNA yields within and between laboratories, and (IV)
composition of total and EV RNAs by reverse transcription-quantitative
polymerase chain reaction (RT-qPCR) and RNA sequencing (RNASeq). The
CSF contained ~106 EVs/μL by NTA and VFC. Brain tumour and SAH CSF
contained more EVs and RNA relative to normal, AD, and PD. RT-qPCR and
RNASeq identified disease-related populations of microRNAs and
messenger RNAs (mRNAs) relative to normal CSF, in both total and EV
fractions. This work presents relevant measures selected to inform the
design of subsequent replicative CSF studies. The range of neurological
diseases highlights variations in total and EV RNA content due to
disease or collection site, revealing critical considerations guiding
the selection of appropriate approaches and controls for CSF studies.
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Deep
sequencing of RNA from three different extracellular vesicle (EV)
subtypes released from the human LIM1863 colon cancer cell line
uncovers distinct miRNA-enrichment signatures.
Ji H, Chen M, Greening DW, He W, Rai A, Zhang W, Simpson RJ
PLoS One. 2014 9(10): e110314 -- eCollection 2014.
Secreted microRNAs
(miRNAs) enclosed within extracellular vesicles (EVs) play a pivotal
role in intercellular communication by regulating recipient cell gene
expression and affecting target cell function. Here, we report the
isolation of three distinct EV subtypes from the human colon carcinoma
cell line LIM1863--shed microvesicles (sMVs) and two exosome
populations (immunoaffinity isolated A33-exosomes and EpCAM-exosomes).
Deep sequencing of miRNA libraries prepared from parental LIM1863
cells/derived EV subtype RNA yielded 254 miRNA identifications, of
which 63 are selectively enriched in the EVs--miR-19a/b-3p,
miR-378a/c/d, and miR-577 and members of the let-7 and miR-8 families
being the most prominent. Let-7a-3p*, let-7f-1-3p*, miR-451a,
miR-574-5p*, miR-4454 and miR-7641 are common to all EV subtypes, and 6
miRNAs (miR-320a/b/c/d, miR-221-3p, and miR-200c-3p) discern LIM1863
exosomes from sMVs; miR-98-5p was selectively represented only in sMVs.
Notably, A33-Exos contained the largest number (32) of
exclusively-enriched miRNAs; 14 of these miRNAs have not been reported
in the context of CRC tissue/biofluid analyses and warrant further
examination as potential diagnostic markers of CRC. Surprisingly, miRNA
passenger strands (star miRNAs) for miR-3613-3p*, -362-3p*, -625-3p*,
-6842-3p* were the dominant strand in A33-Exos, the converse to that
observed in parental cells. This finding suggests miRNA biogenesis may
be interlinked with endosomal/exosomal processing.
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Secreted microRNAs -- a new form of
intercellular communication.
Chen X, Liang H, Zhang J, Zen K, Zhang CY.
Trends Cell Biol. 2012 22(3):125-32
In multicellular
organisms, cell-to-cell communication is of particular
importance for the proper development and function of the organism as a
whole. Intensive studies over the past three years suggesting
horizontal transfer of secreted microRNAs (miRNAs) between cells point
to a potentially novel role for these molecules in intercellular
communication. Using a microvesicle-dependent, or RNA-binding
protein-associated, active trafficking system, secreted miRNAs can be
delivered into recipient cells where they function as endogenous
miRNAs, simultaneously regulating multiple target genes or signaling
events. In this Opinion, we summarize recent literature on the
biogenesis and uptake of secreted miRNAs, propose a possible working
model for how secreted miRNAs might be sorted and transferred between
cells and speculate on their biological significance.
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Characterization of mRNA and microRNA in
human mast cell-derived exosomes and their transfer to other mast cells
and blood CD34 progenitor cells.
Ekström K, Valadi H, Sjöstrand M, Malmhäll C, Bossios A,
Eldh M, Lötvall J.
J Extracell Vesicles. 2012; 1 -- eCollection 2012
BACKGROUND: Exosomes
are nanosized vesicles of endocytic origin that are released into the
extracellular environment by many different cells. It has been shown
that exosomes from various cellular origins contain a substantial
amount of RNA (mainly mRNA and microRNA). More importantly, exosomes
are capable of delivering their RNA content to target cells, which is a
novel way of cell-to-cell communication. The aim of this study was to
evaluate whether exosomal shuttle RNA could play a role in the
communication between human mast cells and between human mast cells and
human CD34(+) progenitor cells.
METHODS: The
mRNA
and microRNA content of exosomes from a human mast cell line, HMC-1,
was analysed by using microarray technology. Co-culture experiments
followed by flow cytometry analysis and confocal microscopy as well as
radioactive labeling experiments were performed to examine the uptake
of these exosomes and the shuttle of the RNA to other mast cells and
CD34(+) progenitor cells.
RESULTS:
In this
study, we show that human mast cells release RNA-containing exosomes,
with the capacity to shuttle RNA between cells. Interestingly, by using
microRNA microarray analysis, 116 microRNAs could be identified in the
exosomes and 134 microRNAs in the donor mast cells. Furthermore, DNA
microarray experiments revealed the presence of approximately 1800
mRNAs in the exosomes, which represent 15% of the donor cell mRNA
content. In addition, transfer experiments revealed that exosomes can
shuttle RNA between human mast cells and to CD34(+) hematopoietic
progenitor cells.
CONCLUSION: These
findings suggest that exosomal shuttle RNA (esRNA) can play a role in
the communication between cells, including mast cells and CD34(+)
progenitor cells, implying a role in cells maturation process.
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... more
papers in the next months !
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