Extracellular Vesicles in Heart Disease: 
Excitement for the Future ? 
 
Review Article 
 
 
 

Kirsty M. Danielson1 and Saumya Das1,* 

1 Cardiovascular Institute, Beth Israel Deaconess Medical Center, Boston, MA 
* Corresponding author E-mail: sdas@bidmc.harvard.edu 

Received 20 Nov 2013; Accepted 10 Feb 2014 
 
DOI: 10.5772/58390 
 
© 2014 The Author(s). Licensee InTech. This is an open access article distributed under the terms of the Creative 
Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, 
distribution, and reproduction in any medium, provided the original work is properly cited. 

 
 
Abstract Extracellular vesicles (EV), including exosomes, 
microvesicles and apoptotic bodies, are released from 
numerous cell types and are involved in intercellular 
communication, physiological functions and the 
pathology of disease. They have been shown to carry and 
transfer a wide range of cargo including proteins, lipids 
and nucleic acids. The role of EVs in cardiac physiology 
and heart disease is an emerging field that has produced 
intriguing findings in recent years. This review will 
outline what is currently known about EVs in the 
cardiovascular system, including cellular origins, 
functional roles and utility as biomarkers and potential 
therapeutics.

Keywords Exosome, Microvesicle, Apoptotic Bodies, 
Cardiovascular Disease 

1. Introduction 

Cardiovascular disease (CVD) is a significant contributor 
to morbidity, mortality and health-care expenditures in 
the United States. With an improvement in earlier 
detection of disease, increased focus on primary 
prevention and better treatment of cardiovascular 
diseases, there has been a steady decline in mortality 

attributable to CVD over the past two decades. 
Nonetheless, the burden of CVD remains extremely high, 
with 32.3% of all U.S deaths directly attributable to CVD 
[1]. Additionally, with the decrease in acute mortality 
after diseases like acute coronary syndrome, treatment of 
cardiovascular conditions including heart failure (the late 
sequelae of myocardial infarctions) now accounts for an 
ever-increasing fraction of health-care expenditure, with 
an estimated 183,000,000,000 dollars spent in 2009 [1]. 
Unfortunately, the development of novel therapies to 
treat CVD has stagnated in the past decade. In light of 
this, there is an urgent need for an improved mechanistic 
understanding of heart disease pathogenesis, the 
identification of novel targets and innovative strategies to 
deliver therapies.  

While cardiomyocytes (CMs) comprise the majority of the 
volume of the heart, multiple other cell types, including 
fibroblasts (which comprise 90% of the non-myocyte cells 
that make up 5-10% of cardiac tissue), endothelial cells 
and vascular smooth muscle cells make up the remainder 
of the heart and play an important role in cardiac 
function, both in health and in disease [2]. Recently, 
investigators have turned their attention to elucidating 
mechanisms of communication between these diverse 
cell-types, particularly as it relates to disease 

1Kirsty M. Danielson and Saumya Das: Extracellular Vesicles in Heart Disease: Excitement for the Future ?

ARTICLE

Exosomes Microvesicles, 2014, 2:1 | doi: 10.5772/58390

Exosomes and Microvesicles



pathogenesis. Extracellular lipid-bilayer enclosed 
particles have garnered recent attention as mediators of 
signalling between cell types [3, 4], particularly in the 
field of immunology and oncology, where their role in 
various processes including intercellular communication 
[5], immune induction [6], neoangiogenesis [7] and 
antigen presentation [8] have been described.  

Investigations into the function of these particles, which 
include exosomes as well as microvesicles (collectively 
referred to as extracellular vesicles or EVs, see definitions 
below), are in their infancy in cardiovascular biology. 
However, several recent studies suggest that these 
particles may not only play an important role in 
intercellular communication in the cardiovascular system, 
but may also have clinical utility as biomarkers in CVD 
and could potentially be utilized as vehicles for targeting 
therapies. This review will focus on the current state of 
knowledge about the role of EVs in the cardiovascular 
system, including characteristics of cardiac EVs and their 
mechanistic function, in addition to their potential use in 
the clinical arena. 

2. Characterization of Cardiac Extracellular Vesicles 

Extracellular vesicles (EVs) consist of several distinct 
entities, namely exosomes, microvesicles and apoptotic 
bodies, which are differentiated by their mechanisms of 
biogenesis and secretion (figure 1). Exosomes are derived 
from the endolysosomal pathway, stored in 
multivesicular bodies and are released from cells through 
fusion of these multivesicular bodies to the cell 
membrane [9]. They are approximately 40-100 nm in 
diameter and investigators have proposed several specific 
surface markers, including tumour susceptibility gene 101 
and flotillin, which identify exosomes [9]. Microvesicles, 
in contrast, are generally larger in size, ranging from 100-
1000 nm in diameter, are formed through budding of the 
cell membrane and thus are heavily enriched in 
phosphatidylserine with a membrane composition that 
resembles that of the parent cell membrane [10]. 
Exosomes and microvesicles contain many cellular 
components capable of effecting intercellular 
communication on neighbouring and distant cells. These 
include cytoplasmic and membrane proteins [11], mRNA 
and microRNA (miRNA) [3], other non-coding RNA [12] 
and lipids [13]. Finally, apoptotic bodies (50-2000 nm) 
result from blebbing of the surface of the apoptotic cells 
and contain cell organelles and nuclear fractions, 
including non-coding RNAs that are specific to the 
nucleus or nucleolus [14].  

Investigators have described detailed characterizations of 
the contents of EVs released by tumour cells [15], cells of 
the immune [16] and neural systems [17] and reviewed 
elsewhere. Much of the recent work has focused on the 

non-coding, particularly the miRNA, content of EVs. Of 
particular interest is work that notes that the miRNA 
profile of EVs is not representative of the parent cell 
miRNA profile, raising the possibility of selective export 
of certain miRNAs into EVs [3]. This observation was 
supported by a subsequent study demonstrating that 
certain miRNAs present in EVs were not detectable in the 
parent tumour cell, thereby suggesting that these 
miRNAs may have been transcribed specifically for 
transport in EVs [18]. At the current time it is not known 
if a similar process of selective transport of miRNAs into 
EVs occurs in the cells that comprise the cardiovascular 
system. 

Figure 1. Extracellular vesicle secretion 

A significant obstacle in this rapidly developing field is 
the lack of standardized protocols for isolating each of 
these components of EVs. Detailed characterization of 
EVs using proteomics [19], lipidomics [13] and RNA-seq 
[20] has also been hindered by the diversity of the cellular 
origins of EVs in biospecimens, coupled with the 
complexity of their contents. Hence published studies 
have shown considerable divergence in their findings, 
with a lack of agreement about standardized surface or 
content markers for each of these components of EVs. 
Current isolation methods for EVs include 
immunoaffinity capture, differential centrifugation, the 
use of gradients and specialized kits produced by 
vendors. These isolation methods rely on different 
characteristics of EVs and therefore it is possible that 
different subpopulations of EVs will be isolated, 
depending on the exact technique deployed. 
Additionally, significant differences in EV viability have 
been found between different preparations [21]. EVs 
produced using ExoQuick (System Biosciences) were 
extremely robust and withstood changes in temperature 
and pH for up to 18 h. By contrast, EVs produced using 
previously published methods for clinical utility 

2 Exosomes Microvesicles, 2014, 2:1 | doi: 10.5772/58390



(ultrafiltration followed by ultracentrifugation through a 
sucrose/deuterium oxide column [22]) began degrading 
and releasing their contents within 2 h [21]. Therefore, 
differences in methods used for EV isolation need to be 
addressed when comparing the findings from different 
studies. 

Differences in EVs from different cell types and species 
should also be taken into consideration. It is likely that 
EVs of different origins express different surface markers; 
therefore, selection of EVs based on specific markers, 
obtained through methods such as immunoaffinity, could 
result in the study of EV subpopulations that exclude 
some biologically relevant carriers. Future detailed 
characterization of EV subpopulations could result in the 
ability to specifically isolate subpopulations of interest, 
which could prove to be a valuable research tool. 

The study of EVs in the cardiovascular field is beset by 
these same complexities. Most studies have relied on 
ultracentrifugation/ultrafiltration techniques to isolate 
EVs; however, some studies call the isolated entities 
exosomes, while others refer to them as extracellular
membrane vesicles (EMVs). Most of these studies do not 
investigate the biogenesis of the isolated EVs or 
characterize their size and composition in detail; hence, in 
our opinion, it would be better to classify to them as EVs. 
In this review, we will therefore refer to these membrane-
bound extracellular vesicles as EVs, regardless of how 
they were classified in the initial publication.

3. Origin of EVs in the Cardiovascular System 

CMs and endothelial cells have both been shown to 
secrete EVs [23, 24]. Like EVs from other cell types, they 
contain a variety of proteins and RNAs from the parent 
cell. Proteomic analysis of EVs (which were classified as 
exosomes in this study) from adult rat CMs revealed 
some common proteins with previous studies from 
different cell origins, including glyceraldehyde-3-
phosphate dehydrogenase (GAPDH) and actin [21]. 
However, many other proteins previously found in EVs 
in other studies, including HSP90 and the tetraspanins, 
were not seen in the CM-derived EVs [21]. In contrast, 
another study did identify previously reported 
tetraspanins in EVs derived from human microvascular 
endothelial cells in culture [24]. It should be noted that 
many of the earlier proteomics studies focused on EVs 
secreted from human tumour cells. The differences in 
protein expression between the EVs of cardiovascular 
origin may reflect differences in both cell type- and 
species- specificity of EV characteristics.  

Currently, no studies have directly demonstrated the 
release of EVs from cardiac fibroblasts. However, in 
neonatal rat cell culture, paracrine factors from cardiac 

fibroblast-cultured media produced changes in CM 
electrophysiology [25] and improved CM viability in 
hypoxic conditions [26]. Investigating whether EVs are 
implicated in mediating these paracrine factors would be 
an interesting area for future research.  

Another interesting finding from proteomics studies is that 
stimulation of cell cultures with different stressors 
produces EVs with differing contents. This was observed in 
both adult rat CMs in response to hypoxia/reoxygenation 
or ethanol treatment [21] and in human microvascular 
endothelial cells in response to hypoxia and TNF-α
treatment [24]. In endothelial cell-derived EVs, several of 
these findings, which were confirmed with immunblot 
analysis, included an increase in lysyl oxidase like-2 in 
EVs from hypoxia-treated cells and an increase in ICAM-
1 in EVs derived from TNF-α treated cells. In addition, 
differences in mRNA expression in endothelial cells in 
response to these stressors were observed [24]. These 
studies raised the possibility that EVs may play a role in 
inter-cellular transfer of stress signals and therefore play 
an important role in disease pathogenesis. 

4. Functional Role of EVs in Cardiovascular Biology  
and Disease  

A summary of reported EV release from different cell 
types in vitro and their functional effects is represented in 
figure 2. 

4.1 Cardiomyocyte-derived EVs 

EV release from CMs (classified as exosomes in this 
study) was first reported by Gupta and Knowlton in 
primary cultures of adult rat CMs, in which EVs were 
isolated using classical differential centrifugation and 
ultracentrifugation techniques [27]. In this study, EVs 
were released from CMs at baseline, but their release 
was tripled (as measured by acetylcholine esterase 
activity [28]) in response to brief hypoxia. HSP60, which 
had not been previously found in EVs from other cell 
types, was determined to be a component of these EVs, 
in addition to the previously described markers HSC70 
and HSP90 [27]. The release of EVs containing TNF-α in 
response to hypoxia has also been reported [29]. In 
neonatal rat CMs, hypoxia induced increases in TNF-α
mRNA within the cell and caused the release of the 26 
kDa transmembrane form of TNF-α in CD63+ EVs. 
Exposure of healthy CMs to these EVs induced 
apoptosis. The authors suggested that although TNF-α is 
not normally produced in the heart, CMs can produce it 
under stress, package it into EVs and thereby affect 
apoptosis in neighbouring cells [29]. Transfer of TNF-α
via EVs may therefore provide a mechanism by which 
stressed cells participate in the propagation of an 
inflammatory response.  

3Kirsty M. Danielson and Saumya Das: Extracellular Vesicles in Heart Disease: Excitement for the Future ?



A subsequent study also showed the release of HSP60-
containing EVs from CMs in response to ethanol 
exposure [21]. The authors argued that this mechanism 
may be reactive oxygen species-mediated, as supported 
by the finding of increased Cell-Rox red staining in the 
ethanol treated cells compared to controls. The 
implications of the HSP60 in the EVs derived from these 
cells remains unclear. HSP60 is found in both the 
mitochondria and cytosol of CMs and has a complex role 
in apoptosis and cell signalling. Increases in HSP60 have 
been reported to prevent apoptosis [30]; however, 
translocation of HSP60 to the plasma membrane has also 
been reported to increase apoptosis [31] and extracellular 
HSP60 (which has been detected in rodent and human 
plasma) appears to contribute to myocardial injury 
during ischemia [32]. In the current study, HSP60 was 
mono-ubiquitinated - associated with lipid raft structures 
- and tightly bound to the membrane surface with the 
EVs. The authors suggested that EV-bound HSP60 
functions as an intercellular signal without causing 
toxicity due to its encapsulation within the membrane, 
although these assumptions were not directly proven 
[21]. Uptake of these exosomes by other cell types and the 
subsequent functional effects were not investigated and 
could be the subject of future studies.  

In contrast to the studies already described, where the 
fate of the secreted exosomes was not directly 
investigated, a recent study demonstrated the transfer of 
DNA and RNA from CMs to fibroblasts [23]. EVs 
released by HL-1 cells (an immortalized atrial myxoma 
cell line) were found to contain DNA and RNA, as 
labelled with acridine orange. When added to NIH-3T3 
cultures, the acridine orange-labelled EVs were shown to 
transfer the acridine orange staining into NIH-3T3 
fibroblasts, often into their nuclei, thereby demonstrating 
EV-mediated transfer of genetic information from CMs to 
fibroblasts. Cargo present within the EVs included 
ribosomal RNA and mRNA coding for proteins and 
transfer of this produced changes in gene expression 
within the fibroblasts [23]. However, the exact mRNAs or 
miRNAs that affected the changes in gene transcription in 
the recipient cells were not identified. Furthermore, since 
NIH-3T3 cells are not a cardiac- specific fibroblast cell 
line, the intriguing idea that there may be differences 
between uptake of CM EVs in cardiac fibroblasts and in 
fibroblasts from other organs was not explored.  

4.2 Stem cell-derived EVs 

In contrast to the limited data on EV secretion by mature 
CMs, considerably more data exist for the release of EVs 
by cardiac progenitor cells (CPCs) and other types of 
stem cells. Spurred by the observation that beneficial 
effects of transplanted CPCs and other types of stem cells 
are often out of proportion to the number of surviving 

engrafted donor cells, investigators have proposed the 
‘paracrine hypothesis’. This hypothesis postulates that in 
addition to possible direct differentiation of the engrafted 
donor stem cells to the appropriate cell lineages, 
paracrine factors released by the donor stem cells may 
contribute to improvements in heart function [33, 34]. 
This has been confirmed by numerous studies that have 
shown that conditioned media from stem cells can 
enhance CM survival after hypoxic injury [35], induce 
angiogenesis in infarcted myocardium [36] and reduce 
infarct size in both mouse [37, 38] and porcine [36, 39] 
models of myocardial ischemia reperfusion injury.  

In many cases, these paracrine factors are packaged 
within EVs. Conditioned media from mesenchymal stem 
cells (MSC) has been shown to reduce infarct size and 
improve cardiac remodelling in a pig model of 
myocardial ischemia/reperfusion and some of this 
activity was contained within EVs isolated by traditional 
ultracentrifugation methods [36]. Similarly, MSC-derived 
EVs inhibited vascular remodelling and attenuated 
hypoxia-induced pulmonary hypertension, probably by 
inhibiting STAT-3 signalling in endothelial cells [40]. At 
least some of the paracrine effects of stem cells in 
recruiting endothelial cells and mediating angiogenesis 
appear to be contained in flotillin-positive 100 nm 
extracellular vesicles (isolated by differential 
ultracentrifugation) [33]. While an extensive 
characterization of the contents of EVs released from the 
different types of stem cell described in these studies has 
not been conducted, much of the recent attention has 
focused on the role of miRNAs packaged in these entities 
[41]. Following in the footsteps of cancer biology, future 
studies will no doubt pinpoint exact miRNAs that are 
packaged and released in EVs and may affect 
surrounding and distant cells. 

4.3 Endothelial cell-derived EVs 

Endothelial cells have been found to be a potent source of 
EVs and several recent studies have shed light on the role 
of EVs in mediating communication between vascular 
endothelial cells, the underlying smooth muscle cells and 
the circulating immune cells in the pathogenesis of 
atherosclerosis.  

At high levels, Ox-LDL and homocysteine are risk factors 
for atherosclerosis and coronary artery disease [42, 43]. In 
contrast, high levels of circulating HSP70 have been 
suggested to be concurrent with a lower risk of vascular 
disease [44]. Both Ox-LDL and homocysteine induced the 
release of exosomes containing HSP70 from rat aortic 
endothelial cells [45]. Interestingly, HSP70 activation of 
monocytes preceded their adhesion to endothelial cells. 
Heat shock proteins are generally accepted to be 
protective within the cell; however, extracellular HSPs 

4 Exosomes Microvesicles, 2014, 2:1 | doi: 10.5772/58390



may be toxic or trigger inflammatory responses. Whether 
monocyte activation by EV-derived HSP70 fulfils a 
protective or deleterious role remains unclear: it could act 
as an early immune response to vascular damage, or 
conversely play a role in early atherosclerotic lesion 
formation via monocyte infiltration of the endothelium. 

Communication between monocytes and endothelial cells 
via EVs occurs in both directions. EVs released from the 
monocytic cell line THP-1 were capable of transferring 
miR-150 to human microvascular endothelial cells 
(HMEC-1) [46]. Similarly, miR-150 enriched EVs isolated 
from human plasma were transferred to HMEC-1 cells; 
however, it was not determined whether they originated 
specifically from monocytes, from another cell type, or 
from multiple cell types. Treating THP-1 cells with 
lipopolysaccharide, hydrogen peroxide, advanced 
glycation end products and oleic acid/palmitic acid 
caused the release of EVs with markedly different 
expression patterns and levels of miRNAs, indicating 
specificity in the packaging and release of miRNAs 
depending on the exact stimulus. The transfer of miR-150 
to HMEC-1 cells via EVs induced migration of these cells, 
presumably through the knock-down of c-Myb [46]. 

In addition to communication between circulating 
monocytes and endothelial cells, the transfer of information 
between endothelial cells and smooth muscle cells may play 
an important role in atherosclerotic plaque formation. 
Disorganization and dysfunction of the smooth muscle cells 
underlying endothelium in the vasculature occurs during 
plaque formation and contributes to pathogenesis [47]. 
Kruppel-like factor 2 (KLF2) is a shear-responsive 
transcription factor believed to be atheroprotective by 
preventing the formation of atherosclerosis [48]. Increased 
expression of KLF2 in human umbilical vein endothelial cells 
(HUVECs) via lentiviral transduction or exposure to shear 
stress causes the release of miR-143/145 in EVs [49]. 
Interestingly, miR-143/145 was increased approximately 
30-fold in EVs compared to only 10-fold in the cells, 
suggesting targeted transcription of the miRNAs 
specifically for release. Co-culture of HUVECs with human 
aortic smooth muscle cells (HASMCs) resulted in the 
transfer of miR-143/145 to the smooth muscle cells and the 
reduction of multiple target mRNAs. Most importantly, 
transfer of miR-143/145 from endothelial cells to smooth 
muscle cells appears to be atheroprotective in vivo. 
Injection of EVs from KLF2-transduced mouse endothelial 
cells into ApoE-/- mice produced a twofold reduction in 
aortic lesion area compared to controls [49].  

Figure 2. Summary of reported EV release from cardiac cells in culture and their functional effects. EV release has been reported in 
numerous cell lines and primary cultures, both at baseline and in response to stimuli. Transfer of EVs between cell types has been
demonstrated as well as delivery of cargo. HUVEC: human aortic endothelial cell; HMEC-1: human microvascular endothelial cell; 
HASMC: human aortic smooth muscle cell; NRVM: neonatal rat ventricular myocyte.

5Kirsty M. Danielson and Saumya Das: Extracellular Vesicles in Heart Disease: Excitement for the Future ?



Finally, evidence of EV-mediated transfer of information 
between endothelial cells and CMs was recently 
demonstrated [50]. While investigating the mechanistic 
basis of peripartum cardiomyopathy, it was found that a 
fragment of prolactin (16K PRL) could induce the 
expression of miR-146a in endothelial cells, leading to 
inhibition of angiogenesis. Furthermore, 16K PRL could 
also induce the release of miR-146a-loaded EVs from 
endothelial cells. These EVs were found to be absorbed 
into CMs where they decreased metabolic activity and 
down-regulated target molecules Erbb4, Notch1 and 
Irak1. Signal transduction by miR-146a packaged in EVs 
appeared to be important in disease pathogenesis, as 
evidenced by amelioration of the disease phenotype by 
antagonism of miR-146a [50].  

The majority of studies on the function of informational 
transfer via EMVs have focused on EVs; however, there is 
evidence that apoptotic bodies also play an important role 
in intercellular communication [51]. Endothelial and 
smooth muscle cell apoptosis have been implicated in the 
pathology of atherosclerosis and apoptotic bodies are 
known to carry an array of DNA fragments, RNA and 
proteins. Indeed, significant enrichment of miR-126 in 
apoptotic bodies released from serum-starved HUVECs 
and HAMSCs has been demonstrated [14]. Application of 
these apoptotic bodies to healthy HUVECs induced 
increased expression of the chemokine CXCL12, which is 
known to recruit progenitor cells and counteract apoptosis 
in response to arterial injury. In addition, HUVEC-derived 
apoptotic bodies induced increased CXCL12 expression in 
HASMCs and mouse aortic endothelial cells. The increase 
in CXCL12 expression was attributed to suppression of 
RGS16 by miR-126. This indicates that the release of miR-
126 enriched apoptotic bodies may non-specifically signal 
to neighbouring vascular cells to promote cell survival. 
Most importantly, miR-126-enriched apoptotic bodies 
derived from atherosclerotic plaques of human patients 
and administered to ApoE-/- mice reduced plaque area and 
macrophage content in the aortic root of mice [14].  

In summary, the studies described above provide 
examples of the functional role of EVs in mediating 
transfer of information and signal transduction between 
endothelial cell types and other important cell types in 
the cardiovascular system. While considerable literature 
exists documenting the important role played by EVs in 
communication between tumour cells and endothelial 
cells, the last two years have seen some progress in 
describing this important mechanism in the 
cardiovascular system and may spur the development of 
novel biomarkers as well as therapeutic targets. 

5. EVs as Biomarkers in the Cardiovascular System 

As previously described, miRNAs and signalling proteins 
specific to the parent cell may be selectively packaged 

into EVs and released into biofluids including plasma, 
urine, saliva and cerebrospinal fluids. In the case of 
tumours, these EVs may contain markers specific for 
these tumours. Apart from their possible functional role 
in altering the tumour microenvironment, the 
sequestration of the RNAs and proteins within the EVs 
protect them from degradation by RNAses and 
proteinases. These characteristics make EVs attractive 
candidates for studying novel biomarkers. This has been 
extensively investigated in the fields of oncology and 
neurology [52, 53]. In cardiovascular biology, there has 
been considerable excitement in studying plasma 
miRNAs as novel diagnostic and prognostic biomarkers. 
While several of the biomarkers described so far 
coincidentally reside within EVs, the use and 
characterization of EVs as biomarkers has not been 
systematically investigated.  

Significantly increased serum levels of miR-1 and miR-
133a has been found in patients with unstable angina 
pectoris, Takotsubo cardiomyopathy and acute 
myocardial infarction [54]. Stimulation of a rat myoblast 
cell line (H9c2) with the calcium ionophore A23187 
induced the release of EVs containing miR-133a. 
Interestingly, miR-133a levels were decreased in infarcted 
heart tissue in a mouse model of myocardial infarction 
and release of EVs from H9c2 cells was associated with 
cell death. This led the authors to conclude that 
circulating miR-133a is released in response to cardiac 
injury and could be used as an indicator of CM death 
[54]. It is not known, however, whether these miRNAs 
contribute to pathology and cell death, or whether they 
may play some compensatory role to prevent the death of 
surrounding cells.  

Sera miR-192, miR-194 and miR-34a were identified as 
prognostic biomarkers in patients with acute myocardial 
infarction. They appeared to predict the development of 
clinical heart failure and ventricular remodelling within 
one year of acute myocardial infarction onset [55]. 
Interestingly, all these miRNAs were regulated by p53 
and packaged in CD63+ EVs. They appear to have a 
deleterious role as transfer of these secreted miRNAs to 
cultured myoblasts from embryonic rat heart accelerated 
cell death, while cell viability was increased by 
knockdown of the three miRNAs [55].  

Endothelial cells have been described as an important 
source of miRNAs packaged into EVs. MiR-146a, as 
described above may play an important role in the 
pathogenesis of peripartum cardiomyopathy by 
mediating signalling between endothelial cells and CMs 
[50]. As noted in the previous section, miR-146a is 
packaged in EVs and released by endothelial cells and in 
human subjects was specifically diagnostic for 
peripartum cardiomyopathy, compared with idiopathic 
dilated cardiomyopathy [50]. 

6 Exosomes Microvesicles, 2014, 2:1 | doi: 10.5772/58390



There have been numerous studies in recent years on 
putative miRNA biomarkers in cardiovascular disease, as 
summarized in [56]. While they have not all been 
identified as membrane-enclosed entities, the 
demonstration of EV release from cardiac cells justifies 
additional investigation into this specific subclass of 
miRNAs. Further evidence supporting the origin of some 
of these biomarker plasma miRNAs in the heart came 
from work that showed a concentration gradient of some 
of the miRNAs recognized as biomarkers of myocardial 
injury, suggesting secretion from myocardial cells [57]. 
Nonetheless, the exact cellular source of these miRNAs, 
the mechanisms of packaging and secretion and their 
functional roles remain a matter of active investigation. 
Thus, there is a rapidly expanding field in identifying and 
validating novel diagnostic and prognostic biomarkers in 
cardiovascular biology. A large majority of these appear 
to be packaged in EVs and therefore protected from 
degradation by circulating RNAses. However, the 
detailed characterization of EVs released into the 
circulation by myocardial cells has lagged behind and 
now appears poised for further fruitful investigation. 

6. EVs as Therapeutic Modalities in Cardiovascular Diseases 

In addition to their use as biomarkers, EVs could 
potentially be used in novel therapeutics for 
cardiovascular disease. As discussed in the previous 
section, several cellular pathways that are targeted by 
EVs originating from cardiac cells have now been 
identified. Possible therapeutic options in cardiovascular 
disease involve targeting the EVs containing RNA, DNA 
or proteins as mediators of signalling pathways involved 
in disease pathogenesis. Blocking the delivery of EV 
cargo to cells could be achieved in several ways, 
including the inhibition of vesicle release, uptake, or 
formation [58]. While no studies have yet described the 
use of such strategies in cardiovascular disease, they have 
been studied to some extent in cancer therapy. For 
example, amiloride-induced inhibition of ceramide, a 
lipid component of sphingomyelin, can reduce vesicle 
yields and it enhanced the efficacy of the chemotherapeutic 
drug cyclophosphamide in mice [59]. A problem with this 
strategy, however, is its potential off-target effects. It is 
now known that many different cell types produce EVs 
and these contain a number of biologically active 
molecules. Therefore a blanket disruption in vesicle 
biology could produce many unwanted effects. 

Alternatively, EVs could be used as therapeutic delivery 
tools. Since EVs are capable of carrying a wide range of 
cargo and transferring exogenous nucleic acids, they are 
an attractive option for gene therapy and drug 
treatments. In addition, some EVs have innate therapeutic 
activity. As discussed previously, transfer of EVs from 
stem cells has been shown to have beneficial effects in 

animal models of cardiovascular disease [36, 37, 39]. This 
suggests two possible strategies for using EVs as a 
therapeutic: deliberate packaging of specific components 
into vesicles for targeted delivery and use of endogenously-
produced stem cell EVs without designed contents. Proof of 
concept for the specific packaging and targeting of EVs has 
been provided by recent studies including [60]. In this study, 
dendritic cells were engineered to express the exosomal 
membrane protein Lamp2b fused to neural specific rabies 
virus glycoprotein peptide. EVs derived from these cells 
were shown to deliver GAPDH siRNA specifically to the 
brain of mice following intravenous injection [60]. Although 
a similar study is yet to be conducted on the cardiovascular 
system, this does provide encouraging evidence for the 
viability of EVs as a therapeutic modality. Furthermore, 
methods for the large scale production of clinical grade EVs 
from dendritic cells [22] and mesenchymal stem cells [61,62] 
are currently being developed and offer considerable 
promise. With continuing research on the role and 
regulation of EVs in cardiovascular disease, they could offer 
a novel therapeutic tool in the future. 

7. Conclusion 

In summary, EVs released from cardiovascular cells have 
been shown to transfer to different cell types and cause 
changes in RNA and protein expression that have 
significant downstream functional effects. Functional 
changes reported to date appear be both protective and 
deleterious and may play an important role in normal 
physiology or disease pathogenesis. Regardless of whether 
the observed effects of EV transfer produce positive or 
negative effects, EVs provide an attractive target for 
potential therapies and use as novel biomarkers.  

There is considerable uncharted territory that is yet to be 
explored by investigators. EVs have been shown to express 
surface ligands such as integrins that can interact with 
proteins of the extracellular matrix, where they may be 
stored as repositories of signalling. Alterations in the 
extracellular matrix, as may occur with infarction or 
haemodynamic changes resulting from heart failure may 
result in the ‘uncovering’ of these EVs and their signalling 
capabilities. This hypothesis has been explored in cancer 
biology, but remains to be examined in heart disease.  

Detailed characterization of EVs released by the components 
of the cardiovascular system both at baseline and with stress 
may provide additional insight into novel intercellular 
signalling mechanisms. As attempts to undertake these 
ventures gather pace, we may be on the threshold of a new 
era of mechanistic understanding of heart disease. 

8. Acknowledgements 

SD is funded by the Klarman Scholars Foundation. 

7Kirsty M. Danielson and Saumya Das: Extracellular Vesicles in Heart Disease: Excitement for the Future ?



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