Abstract
Extracellular vesicles (EVs) from mesenchymal stem cells (MSCs) are microvesicles produced from cells throughout their life. From research over recent years, there has been greater understanding about EVs, including their physiological characteristics and the role they play in cell targets. Indeed, EVs carry information (in the form of RNA, DNA and protein) to cell targets. Some of their main biological properties include angiogenesis and immune-modulation. Therefore, these properties can be exploited to treat various diseases, including bone disorders, spinal cord injury and diabetes mellitus. Recently, new methods have been developed to isolate and enrich EVs with high performance and low-toxicity. Thus, EVs have emerged as the new generation of stem cell therapy. This concise review aims to highlight some recent achievements of EVs in preclinical and clinical applications.
Introduction
Stem cells are unspecialized cells with long-lasting self-renewal potential. After differentiation they can become specialized cells with new physiological functions Bongso and Lee, 2005. In recent years, stem cells have been discovered to exhibit other useful functions, including secretion of cytokines Kilroy et al., 2007, i.e. growth factors which help stimulate tissue regeneration Boomsma and Geenen, 2012, and notably immune modulation of mesenchymal stem cells Abdi et al., 2008da Silva Meirelles et al., 2009Prockop and Oh, 2012Yanez et al., 2006. To date, stem cells (particularly MSCs) have been discovered to have at least 3 functionst: homing and differentiation into tissue specialized cells, production of cytokines and growth factors, and immune modulation.
Given these functions, stem cells have been tested for various diseases; in fact over the last 50 years they have been evaluated in more than 50 different diseases Ginn et al., 2013Squillaro et al., 2016Van Pham, 2016. Hematopoietic stem cell transplantation has been widely used to treat hematopoietic malignancies, and MSC therapy has already been approved as routine treatment for a number of diseases in Canada, Japan, Korea, China, India and Vietnam. Compared to HSCs, MSCs play many more functions in vivo and possess unique characteristics, such as immune modulation and tissue healing via secreted factors Chase and Vemuri, 2012.
One of the most well-known secreted factors is extracellular vesicles (EVs). EVs have distinct physiological characteristics and have been studied for disease applications for the past 5 years. This review aims to summarize the characteristics of EVs and their applications in the clinic.
What are extracellular vesicles?
Extracellular vesicles are nano-sized particles produced from the live cells during their lifespan. EVs can be classified into two main kinds based on their size: exosomes and microvesicles. Exosomes are about 40-150 nm in diameter whereas microvesicles are about 50nm-2000 nm in diameter. They differ in the way they are produced and, thus, exosomes and microvesicles exhibit different properties.
Generally, exosomes are produced from secretory mechanisms and are regulated by endosomal sorting complex mechanisms, which are associated with transport proteins (e.g. ESCRT), Rab proteins, tumor protein p53 pathway, tumor suppressor-activated pathway 6, and ceramide/neutral sphingomyelinase Lespagnol et al., 2008Ostrowski et al., 2010Rak, 2013. Moreover, exosomes are rich in tetraspanins (CD63, CD81, CD9, etc.), gangliosides, sphingomyelin, and saturated lipids. Exosomes generally have a more rigid membrane than that of microvesicles which allow them to be more resistant to degradation and thus more stable Pols and Klumperman, 2009Raposo and Stoorvogel, 2013Stoorvogel et al., 2002.
Microvesicles are directly produced from the plasma cellular membrane and therefore they contain some cytoplasmic components. Unlike exosomes, microvesicles contain markers of the original cells, such as common proteins of the cellular membrane like integrins, glycoprotein Ib (GPIb), and P-selectin Kastelowitz and Yin, 2014Raposo and Stoorvogel, 2013.
Besides exosomes and microvesicles, apoptotic bodies and oncosomes can also be found in EVs Crescitelli et al., 2013Meehan et al., 2016. Apoptotic bodies are products of the apoptotic process while oncosomes are larger vesicles produced from cancer cells.
Physiological functions of EVs
EVs are comprised of exosomes, microvesicles, apoptotic bodies and oncosomes, and play important physiological roles, especially in cellular communication. They are important not only in the normal physiological processes but also in pathological conditions. The roles that EVs play are dependent on the content they cargo. It was initially discovered that EVs contain siRNA molecules Eirin et al., 2014Kumar et al., 2015Lai et al., 2015Vallabhaneni et al., 2015. Nowadays, it is known that they carry many more forms of “information”. In fact, exosomes have been described as “information cargos” for their transport of siRNA, DNA, peptides, and proteins Baglio et al., 2012Biancone et al., 2012Camussi et al., 2010Lai et al., 2015Rani et al., 2015Yu et al., 2014. All of these aforementioned molecules help regulate cell targeting by modulating gene expression and gene regulation in target cells at the level of post-transcription and translation Camussi et al., 2011Collino et al., 2010Mokarizadeh et al., 2012Zhang et al., 2015b.
EVs from mesenchymal stem cells (MSCs)
It has been known for over a decade that MSCs can produce EVs. MSC-derived EVs (MSC-EVs) contain at least 2 components: exosomes and microvesicles. Both exosomes and microvesicles express tetraspanin molecules and MSC markers on their surface; these include CD9, CD63, CD81 and CD107, and CD29, CD73, CD44 and CD105, respectively Lai et al., 2015Yu et al., 2014.
The components inside EVs have been the focus of many research studies Baglio et al., 2012Lo Sicco et al., 2017Wang et al., 2017Yuan et al., 2017. The main components found inside MSC-EVs are miRNAs De Luca et al., 2016Fafian-Labora et al., 2017 Livingston and Wei. Notably, MSC-EVs have been found to contain miR-223, miR-564, and miR-451 De Luca et al., 2016Nawaz et al., 2016. These miRNAs play the important roles in cell survival, cell differentiation, and immune regulation Yanez-Mo et al., 2015). Besides miRNAs, other RNAs can be found in MSC-EVs Borger et al., 2017. Such RNAs include transcription factor CP2/clock homolog (which regulates transcription), retinoblastoma-like 1 (which also regulates transcription), small ubiquitin-related modifier 1 (which regulates cell proliferation), and interleukin-1 receptor antagonist (which regulates immune responses) Tomasoni et al., 2013.
MSC-EVs are generally comprised of 3 main groups of proteins/molecules, including surface receptors, signaling molecules, and cell adhesion molecules. These proteins were demonstrated to regulate cell self-renewal and differentiation. Surface receptors and cell adhesion molecules are present on the surface of EVs, and likely originated from cell membrane. Conversely, signaling molecules are usually found within EVs, and likely originated from secretory processes. Some common surface receptors found in MSC-EVs include platelet-derived growth factor receptor, epidermal growth factor receptor, and plasminogen activator urokinase receptor. Some common cell adhesion proteins include fibronectin, ezrin, IQ motif containing GTPase activating protein 1, CD47, integrins, lectin galactose binding soluble 1 (LGALS1), and lectin galactose binding soluble 3 (LGALS3) ( Figure 1 ).
Other important molecules to be found within MSC-EVs include RAS-related protein/neuroblastoma RAS, mitogen-activated protein kinase 1 (MAPK1), guanine nucleotide-binding protein subunit 13/G protein subunit 12 (GNA13/ GNG12), cell division control protein 42 homolog, Vav guanine nucleotide exchange factor 2, transforming growth factor beta, mitogen-activated protein kinase, and peroxisome proliferator-activated receptor Baglio et al., 2012. Given these important aforementioned components, MSC-EVs represent a cellular therapeutic approach with great potential in regenerative medicine ( Figure 1 ).
Applications of EVs
Critical size bone defects
MSCs-EVs have been evaluated for treatment of certain bone defects. Recently, MSC-EVs were shown to stimulate bone regeneration in a bone defect model Qin et al., 2016. MSC-EVs promoted cartilage restoration and subchondral bone regeneration in osteochondral defects Zhang et al., 2016. They were also capable of preventing bone loss and enhancing neo-angiogenesis in a femoral head necrosis model Liu et al., 2017. Qin et al. (2016) isolated MSC-EVs by gradient ultracentrifugation and ultrafiltration. These EVs were used to treat osteogenesis both in vitro and in vivo. The authors showed that MSC-EVs could induce bone formation in Sprague Dawley rats with calvarial defects Qin et al., 2016. Qin et al. showed evidence that miR-196a in MSC-EVs may play an essential role in the regulation of osteoblast differentiation Qin et al., 2016.
Zhang et al. (2016) also tested the intra-articular injection of 100 ug EVs per rat bearing osteochondral defects (n=12 adult rats); the EVs were derived from human embryonic MSCs. After 12 weeks of injection, the EV-treated group showed an histological score greater than that of PBS. Moreover, cartilage and subchondral bone were restored Zhang et al., 2016.
EVs derived from MSCs can differentiate from induced pluripotent stem cells, according to a study by Liu et al. (2017) Liu et al., 2017. Indeed, EVs are sometimes referred to as induced pluripotent stem cell-/differentiated mesenchymal stem cell-derived exosomes (iPS-MSC-Exos). These exosomes can stimulate endothelial cells to proliferate and migrate, and stimulate tube forming via expression of PI3K/Akt signaling pathway Liu et al., 2017. By this mechanism, the iPS-MSC-Exos can prevent the bone loss and increase microvessel density in the femoral head compared to the placebo group in the rat model.
Epidermolysis bullosa (EB)
Epidermolysis bullosa (EB) is a rare genetic disorder of which dystrophic epidermolysis bullosa (DEB), which causes skin fragility, is one of the major forms. In this disorder, patients lack collagen type 7 (C7) and have defective anchoring fibrils at the dermal-epidermal junctions (Fine et al., 2014). Recently, this disease was treated by infusion of the MSC-EVs. EVs derived from human embryonic stem cell differentiation, from human biblical cord, and from adipose tissue were used to treat this disease in animal models. The first pre-clinical trial was conducted in a murine model; the authors injected MSC-EVs (from human ESCs) and evaluated allogenic skin grafts in the mouse model. The results showed that the infusion induced the M2 phenotype in monocytes in vitro and regulatory T cell polarization in vivo, as well as enhanced the survival of skin grafts Zhang et al., 2014.
EVs from umbilical cord-MSCs have demonstrated to activate the WNT4 signaling pathway in deep second degree burn injury in rats. Therefore, these EVs can accelerate skin regeneration Zhang et al., 2015a. EVs from ADSCs can recruit fibroblasts to the wound areas, increase collagen type I and III, and reduce scar formation Hu et al., 2016.
Spinal cord injury (SCI)
Spinal cord injury is a condition related to a disconnection of axons which direct signals from the brain to peripheral organs. Injection of EVs was shown to be an effective treatment for SCI in animals. Both EVs from MSCs and embryonic neurons successfully reduced inflammation and promoted neuro-regeneration in rats after SCI Doeppner et al., 2015Han et al., 2015Rivero Vaccari et al., 2016. The mechanisms of action are likely a weakening of TLR4 mediated signaling and reduction of the IL-1beta and TNF-alpha axes Teixeira et al., 2015.
GVHD in hematopoietic stem cell transplantation
Graft versus host disease (GVHD) is a common condition that arises in almost all cases of hematopoietic stem cell transplantation (HSCT), especially allo-graft transplantation. GVHD arises when the new immune system that comes from the HSCs attack to the owner cells. Recently, EVs from MSCs can contribute to improving the allo-HSCT allograft. Indeed, the MSC-EVs can modulate the immune system Blazquez et al., 2014Budoni et al., 2013Chen et al., 2016Conforti et al., 2014, therefore, they can be used to prevent or reduce the immunoreactions as GVHD. In the clinical study, Kordelas et at. showed that bone marrow MSC-EVs could alleviate the GVHD symptoms in grade IV GVHD patients with no side effects Kordelas et al., 2014. This study also showed that MSC-EVs contained some anti-inflammatory factors included IL-10, TGF-beta and HLA-G.
In another study in animal model, Wang et al. also showed that umbilical cord blood derived MSCs-EVs can prevent the acute GVHD in mouse model of allo-HSCT Wang et al., 2016.
Acute renal injury
Acute renal failure (ARF) is characterized by the loss of renal function with concurrent accumulation of creatinine and nitrogen metabolism products (e.g. urea). This condition is associated with ischemia, reperfusion injury, and/or exposure to nephrotoxic agents. The effects of EVs in ARF have been investigated in some models of ARF, including models of kidney injury induced by glycerol, cisplatin, and gentamicin. In these models, high inflammatory reactions were observed, with an increase of interstitial infiltrate, apoptosis and tubular necrosis. MSC-EVs have been evaluated as treatment in these models. In almost all cases, injection of EVs decreased inflammation and inhibited apoptosis. To date, there are 3 clinical trials using MSCs to evaluate the efficacy and safety of ARF: NCT01275612, NCT00733876 and NCT01602328. However, there has not been any clinical trial using EVs for the treatment of ARF.
Diabetes mellitus
The first documented study showing the application of MSC-EVs for treatment of diabetes type 1 (T1D) was reported this year; Shigemoto-Kuroda et al. (2017) demonstrated that MSC-EVs effectively prevented the onset of disease in T1D. In this study, the authors showed that the effects MSC-EVs were similar to that of MSCs in terms of immune modulation potential. EVs have been shown to be capable of inhibiting antigen presenting cells, and Th1 and Th17 cells Shigemoto-Kuroda et al..
Conclusion
EVs from MSCs contain some biological components such as DNA, RNA and proteins. These molecules help EVs exhibit particular physiological activities and functions, similar to those of MSCs, such as stimulation of tissue regeneration and immune modulation. Therefore, EVs from MSCs have become increasingly popular to study in recent years. Importantly, primary investigations have indicated the promise of EVs in applications of regenerative medicine.
Abbreviations
ARF: Acute renal failure
EB: Epidermolysis bullosa
EVs: Extracellular vesicles
GVHD: Graft versus host disease
HSCT: Hematopoietic stem cell transplantation
MSCs: Mesenchymal stem cells
SCI: Spinal cord injury
T1D: Diabetes type 1
References
-
R.
Abdi,
P.
Fiorina,
C.N.
Adra,
M.
Atkinson,
M.H.
Sayegh.
Immunomodulation by mesenchymal stem cells. Diabetes.
2008;
57
:
1759-1767
.
-
S.R.
Baglio,
D.M.
Pegtel,
N.
Baldini.
Mesenchymal stem cell secreted vesicles provide novel opportunities in (stem) cell-free therapy. Frontiers in physiology.
2012;
3
.
-
L.
Biancone,
S.
Bruno,
M.C.
Deregibus,
C.
Tetta,
G.
Camussi.
Therapeutic potential of mesenchymal stem cell-derived microvesicles. Nephrology Dialysis Transplantation.
2012;
27
:
3037-3042
.
-
R.
Blazquez,
F.M.
Sanchez-Margallo,
O.
de la Rosa,
W.
Dalemans,
V.
Álvarez,
R.
Tarazona,
J.G.
Casado.
Immunomodulatory potential of human adipose mesenchymal stem cells derived exosomes on in vitro stimulated T cells. Frontiers in immunology.
2014;
5
.
-
A.
Bongso,
E.H.
Lee.
Stem cells: from bench to bedside. World Scientific.
2005
.
-
R.A.
Boomsma,
D.L.
Geenen.
Mesenchymal stem cells secrete multiple cytokines that promote angiogenesis and have contrasting effects on chemotaxis and apoptosis. PloS one.
2012;
7
:
e35685
.
-
V.
Borger,
M.
Bremer,
R.
Ferrer-Tur,
L.
Gockeln,
O.
Stambouli,
A.
Becic,
B.
Giebel.
Mesenchymal Stem/Stromal Cell-Derived Extracellular Vesicles and Their Potential as Novel Immunomodulatory Therapeutic Agents. Int J Mol Sci.
2017;
18
.
-
M.
Budoni,
A.
Fierabracci,
R.
Luciano,
S.
Petrini,
V.
Di Ciommo,
M.
Muraca.
The immunosuppressive effect of mesenchymal stromal cells on B lymphocytes is mediated by membrane vesicles. Cell transplantation.
2013;
22
:
369-379
.
-
G.
Camussi,
M.-C.
Deregibus,
S.
Bruno,
C.
Grange,
V.
Fonsato,
C.
Tetta.
Exosome/microvesicle-mediated epigenetic reprogramming of cells. American journal of cancer research.
2011;
1
:
98
.
-
G.
Camussi,
M.C.
Deregibus,
S.
Bruno,
V.
Cantaluppi,
L.
Biancone.
Exosomes/microvesicles as a mechanism of cell-to-cell communication. Kidney international.
2010;
78
:
838-848
.
-
L.G.
Chase,
M.C.
Vemuri.
Mesenchymal stem cell therapy. Springer Science & Business Media.
2012
.
-
W.
Chen,
Y.
Huang,
J.
Han,
L.
Yu,
Y.
Li,
Z.
Lu,
H.
Li,
Z.
Liu,
C.
Shi,
F.
Duan.
Immunomodulatory effects of mesenchymal stromal cells-derived exosome. Immunologic research.
2016;
64
:
831-840
.
-
F.
Collino,
M.C.
Deregibus,
S.
Bruno,
L.
Sterpone,
G.
Aghemo,
L.
Viltono,
C.
Tetta,
G.
Camussi.
Microvesicles derived from adult human bone marrow and tissue specific mesenchymal stem cells shuttle selected pattern of miRNAs. PloS one.
2010;
5
:
e11803
.
-
A.
Conforti,
M.
Scarsella,
N.
Starc,
E.
Giorda,
S.
Biagini,
A.
Proia,
R.
Carsetti,
F.
Locatelli,
M.E.
Bernardo.
Microvescicles derived from mesenchymal stromal cells are not as effective as their cellular counterpart in the ability to modulate immune responses in vitro. Stem cells and development.
2014;
23
:
2591-2599
.
-
R.
Crescitelli,
C.
Lässer,
T.G.
Szabo,
A.
Kittel,
M.
Eldh,
I.
Dianzani,
E.I.
Buzás,
J.
Lötvall.
Distinct RNA profiles in subpopulations of extracellular vesicles: apoptotic bodies, microvesicles and exosomes. Journal of extracellular vesicles.
2013;
2
:
20677
.
-
L.
Silva Meirelles,
A.M.
Fontes,
D.T.
Covas,
A.I.
Caplan.
Mechanisms involved in the therapeutic properties of mesenchymal stem cells. Cytokine & growth factor reviews.
2009;
20
:
419-427
.
-
L.
De Luca,
S.
Trino,
I.
Laurenzana,
V.
Simeon,
G.
Calice,
S.
Raimondo,
M.
Podesta,
M.
Santodirocco,
L.
Di Mauro,
F.
La Rocca.
MiRNAs and piRNAs from bone marrow mesenchymal stem cell extracellular vesicles induce cell survival and inhibit cell differentiation of cord blood hematopoietic stem cells: a new insight in transplantation. Oncotarget.
2016;
7
:
6676-6692
.
-
T.R.
Doeppner,
J.
Herz,
A.
Görgens,
J.
Schlechter,
A.-K.
Ludwig,
S.
Radtke,
K.
de Miroschedji,
P.A.
Horn,
B.
Giebel,
D.M.
Hermann.
Extracellular vesicles improve post - stroke neuroregeneration and prevent postischemic immunosuppression. Stem cells translational medicine.
2015;
4
:
1131-1143
.
-
A.
Eirin,
S.M.
Riester,
X.-Y.
Zhu,
H.
Tang,
J.M.
Evans,
D.
O'Brien,
A.J.
van Wijnen,
L.O.
Lerman.
MicroRNA and mRNA cargo of extracellular vesicles from porcine adipose tissue-derived mesenchymal stem cells. Gene.
2014;
551
:
55-64
.
-
J.
Fafian-Labora,
I.
Lesende-Rodriguez,
P.
Fernandez-Pernas,
S.
Sangiao-Alvarellos,
L.
Monserrat,
O.J.
Arntz,
F.J.
Loo,
J.
Mateos,
M.C.
Arufe.
Effect of age on pro-inflammatory miRNAs contained in mesenchymal stem cell-derived extracellular vesicles. Scientific reports.
2017;
7
:
43923
.
-
S.L.
Ginn,
I.E.
Alexander,
M.L.
Edelstein,
M.R.
Abedi,
J.
Wixon.
Gene therapy clinical trials worldwide to 2012-an update. The journal of gene medicine.
2013;
15
:
65-77
.
-
D.
Han,
C.
Wu,
Q.
Xiong,
L.
Zhou,
Y.
Tian.
Anti-inflammatory mechanism of bone marrow mesenchymal stem cell transplantation in rat model of spinal cord injury. Cell biochemistry and biophysics.
2015;
71
:
1341-1347
.
-
L.
Hu,
J.
Wang,
X.
Zhou,
Z.
Xiong,
J.
Zhao,
R.
Yu,
F.
Huang,
H.
Zhang,
L.
Chen.
Exosomes derived from human adipose mensenchymal stem cells accelerates cutaneous wound healing via optimizing the characteristics of fibroblasts. Scientific reports.
2016;
6
:
32993
.
-
N.
Kastelowitz,
H.
Yin.
Exosomes and microvesicles: identification and targeting by particle size and lipid chemical probes. Chembiochem.
2014;
15
:
923-928
.
-
G.E.
Kilroy,
S.J.
Foster,
X.
Wu,
J.
Ruiz,
S.
Sherwood,
A.
Heifetz,
J.W.
Ludlow,
D.M.
Stricker,
S.
Potiny,
P.
Green.
Cytokine profile of human adipose-derived stem cells: expression of angiogenic, hematopoietic, and pro-inflammatory factors. Journal of cellular physiology.
2007;
212
:
702-709
.
-
L.
Kordelas,
V.
Rebmann,
A.K.
Ludwig,
S.
Radtke,
J.
Ruesing,
T.R.
Doeppner,
M.
Epple,
P.A.
Horn,
D.W.
Beelen,
B.
Giebel.
MSC-derived exosomes: a novel tool to treat therapy-refractory graft-versus-host disease. Leukemia.
2014;
28
.
-
L.
Kumar,
S.
Verma,
B.
Vaidya,
V.
Gupta.
Exosomes: natural carriers for siRNA delivery. Current pharmaceutical design.
2015;
21
:
4556-4565
.
-
R.C.
Lai,
R.W.Y.
Yeo,
S.K.
Lim.
Mesenchymal stem cell exosomes. Paper presented at: Seminars in Cell & Developmental Biology (Elsevier).
2015
.
-
A.
Lespagnol,
D.
Duflaut,
C.
Beekman,
L.
Blanc,
G.
Fiucci,
J.C.
Marine,
M.
Vidal,
R.
Amson,
A.
Telerman.
Exosome secretion, including the DNA damage-induced p53-dependent secretory pathway, is severely compromised in TSAP6/ Steap3-null mice. Cell death and differentiation.
2008;
15
:
1723-1733
.
-
X.
Liu,
Q.
Li,
X.
Niu,
B.
Hu,
S.
Chen,
W.
Song,
J.
Ding,
C.
Zhang,
Y.
Wang.
Exosomes Secreted from Human-Induced Pluripotent Stem Cell-Derived Mesenchymal Stem Cells Prevent Osteonecrosis of the Femoral Head by Promoting Angiogenesis. International journal of biological sciences.
2017;
13
:
232-244
.
-
M.J.
Livingston,
Q.
Wei.
MicroRNAs in extracellular vesicles protect kidney from ischemic injury: from endothelial to tubular epithelial. Kidney International.
;
90
:
1150-1152
.
-
C.
Lo Sicco,
D.
Reverberi,
C.
Balbi,
V.
Ulivi,
E.
Principi,
L.
Pascucci,
P.
Becherini,
M.C.
Bosco,
L.
Varesio,
C.
Franzin.
Mesenchymal Stem Cell-Derived Extracellular Vesicles as Mediators of Anti-Inflammatory Effects: Endorsement of Macrophage Polarization. Stem Cells Transl Med.
2017;
6
:
1018-1028
.
-
B.
Meehan,
J.
Rak,
D.
Di Vizio.
Oncosomes-large and small: what are they, where they came from?. Journal of extracellular vesicles.
2016;
5
.
-
A.
Mokarizadeh,
N.
Delirezh,
A.
Morshedi,
G.
Mosayebi,
A.-A.
Farshid,
K.
Mardani.
Microvesicles derived from mesenchymal stem cells: potent organelles for induction of tolerogenic signaling. Immunology letters.
2012;
147
:
47-54
.
-
M.
Nawaz,
F.
Fatima,
K.C.
Vallabhaneni,
P.
Penfornis,
H.
Valadi,
K.
Ekstrom,
S.
Kholia,
J.D.
Whitt,
J.D.
Fernandes,
R.
Pochampally.
Extracellular Vesicles: Evolving Factors in Stem Cell Biology. Stem cells international.
2016;
2016
:
1073140
.
-
M.
Ostrowski,
N.B.
Carmo,
S.
Krumeich,
I.
Fanget,
G.
Raposo,
A.
Savina,
C.F.
Moita,
K.
Schauer,
A.N.
Hume,
R.P.
Freitas.
Rab27a and Rab27b control different steps of the exosome secretion pathway. Nature cell biology.
2010;
12
:
19-30; sup pp 11
.
-
M.S.
Pols,
J.
Klumperman.
Trafficking and function of the tetraspanin CD63. Experimental cell research.
2009;
315
:
1584-1592
.
-
D.J.
Prockop,
J.Y.
Oh.
Mesenchymal stem/stromal cells (MSCs): role as guardians of inflammation. Molecular Therapy.
2012;
20
:
14-20
.
-
Y.
Qin,
L.
Wang,
Z.
Gao,
G.
Chen,
C.
Zhang.
Bone marrow stromal/stem cell-derived extracellular vesicles regulate osteoblast activity and differentiation in vitro and promote bone regeneration in vivo. Scientific reports.
2016;
6
:
21961
.
-
J.
Rak.
Extracellular vesicles - biomarkers and effectors of the cellular interactome in cancer. Frontiers in pharmacology.
2013;
4
:
21
.
-
S.
Rani,
A.E.
Ryan,
M.D.
Griffin,
T.
Ritter.
Mesenchymal stem cell-derived extracellular vesicles: toward cell-free therapeutic applications. Mol Ther.
2015;
23
.
-
G.
Raposo,
W.
Stoorvogel.
Extracellular vesicles: exosomes, microvesicles, and friends. J Cell Biol.
2013;
200
:
373-383
.
-
J.P.
Rivero Vaccari,
F.
Brand,
S.
Adamczak,
S.W.
Lee,
J.
Perez-Barcena,
M.Y.
Wang,
M.R.
Bullock,
W.D.
Dietrich,
R.W.
Keane.
Exosome-mediated inflammasome signaling after central nervous system injury. Journal of neurochemistry.
2016;
136
:
39-48
.
-
T.
Shigemoto-Kuroda,
J.Y.
Oh,
D.-k.
Kim,
H.J.
Jeong,
S.Y.
Park,
H.J.
Lee,
J.W.
Park,
T.W.
Kim,
S.Y.
An,
D.J.
Prockop.
MSC-derived Extracellular Vesicles Attenuate Immune Responses in Two Autoimmune Murine Models: Type 1 Diabetes and Uveoretinitis. Stem Cell Reports.
;
8
:
1214-1225
.
-
T.
Squillaro,
G.
Peluso,
U.
Galderisi.
Clinical trials with mesenchymal stem cells: an update. Cell transplantation.
2016;
25
:
829-848
.
-
W.
Stoorvogel,
M.J.
Kleijmeer,
H.J.
Geuze,
G.
Raposo.
The biogenesis and functions of exosomes. Traffic.
2002;
3
:
321-330
.
-
F.G.
Teixeira,
M.M.
Carvalho,
A.
Neves-Carvalho,
K.M.
Panchalingam,
L.A.
Behie,
L.
Pinto,
N.
Sousa,
A.J.
Salgado.
Secretome of mesenchymal progenitors from the umbilical cord acts as modulator of neural/glial proliferation and differentiation. Stem Cell Reviews and Reports.
2015;
11
:
288-297
.
-
S.
Tomasoni,
L.
Longaretti,
C.
Rota,
M.
Morigi,
S.
Conti,
E.
Gotti,
C.
Capelli,
M.
Introna,
G.
Remuzzi,
A.
Benigni.
Transfer of growth factor receptor mRNA via exosomes unravels the regenerative effect of mesenchymal stem cells. Stem Cells Dev.
2013;
22
:
772-780
.
-
K.C.
Vallabhaneni,
P.
Penfornis,
S.
Dhule,
F.
Guillonneau,
K.V.
Adams,
Y.Y.
Mo,
R.
Xu,
Y.
Liu,
K.
Watabe,
M.C.
Vemuri.
Extracellular vesicles from bone marrow mesenchymal stem/stromal cells transport tumor regulatory microRNA, proteins, and metabolites. Oncotarget.
2015;
6
:
4953
.
-
P.
Van Pham.
Clinical application of stem cells: An update 2015. Biomedical Research and Therapy.
2016;
3
:
483-489
.
-
J.
Wang,
P.
Cen,
J.
Chen,
L.
Fan,
J.
Li,
H.
Cao,
L.
Li.
Role of mesenchymal stem cells, their derived factors, and extracellular vesicles in liver failure. Stem Cell Research & Therapy.
2017;
8
:
137
.
-
L.
Wang,
Z.
Gu,
X.
Zhao,
N.
Yang,
F.
Wang,
A.
Deng,
S.
Zhao,
L.
Luo,
H.
Wei,
L.
Guan.
Extracellular vesicles released from human umbilical cord-derived mesenchymal stromal cells prevent life-threatening acute graft-versus-host disease in a mouse model of allogeneic hematopoietic stem cell transplantation. Stem cells and development.
2016;
25
:
1874-1883
.
-
R.
Yanez,
M.L.
Lamana,
J.
García-Castro,
I.
Colmenero,
M.
Ramirez,
J.A.
Bueren.
Adipose Tissue-Derived Mesenchymal Stem Cells Have In Vivo Immunosuppressive Properties Applicable for the Control of the Graft-Versus-Host Disease. Stem cells.
2006;
24
:
2582-2591
.
-
M.
Yanez-Mo,
P.R.
Siljander,
Z.
Andreu,
A.B.
Zavec,
F.E.
Borras,
E.I.
Buzas,
K.
Buzas,
E.
Casal,
F.
Cappello,
J.
Carvalho.
Biological properties of extracellular vesicles and their physiological functions. J Extracellular Vesicles.
2015;
4
.
-
B.
Yu,
X.
Zhang,
X.
Li.
Exosomes derived from mesenchymal stem cells. International journal of molecular sciences.
2014;
15
:
4142-4157
.
-
Z.
Yuan,
K.K.
Kolluri,
K.H.C.
Gowers,
S.M.
Janes.
TRAIL delivery by MSC-derived extracellular vesicles is an effective anticancer therapy. Journal of Extracellular Vesicles.
2017;
6
:
1265291
.
-
B.
Zhang,
M.
Wang,
A.
Gong,
X.
Zhang,
X.
Wu,
Y.
Zhu,
H.
Shi,
L.
Wu,
W.
Zhu,
H.
Qian.
HucMSC-Exosome Mediated-Wnt4 Signaling Is Required for Cutaneous Wound Healing. Stem Cells.
2015a;
33
:
2158-2168
.
-
B.
Zhang,
X.
Wu,
X.
Zhang,
Y.
Sun,
Y.
Yan,
H.
Shi,
Y.
Zhu,
L.
Wu,
Z.
Pan,
W.
Zhu.
Human umbilical cord mesenchymal stem cell exosomes enhance angiogenesis through the Wnt4/β-catenin pathway. Stem cells translational medicine.
2015b;
4
:
513-522
.
-
B.
Zhang,
Y.
Yin,
R.C.
Lai,
S.S.
Tan,
A.B.
Choo,
S.K.
Lim.
Mesenchymal stem cells secrete immunologically active exosomes. Stem Cells Dev.
2014;
23
.
-
S.
Zhang,
W.C.
Chu,
R.C.
Lai,
S.K.
Lim,
J.H.
Hui,
W.S.
Toh.
Exosomes derived from human embryonic mesenchymal stem cells promote osteochondral regeneration. Osteoarthritis and cartilage.
2016;
24
:
2135-2140
.
Comments
Downloads
Article Details
Volume & Issue : Vol 4 No 08 (2017)
Page No.: 1562-1573
Published on: 2017-08-28
Citations
Copyrights & License
This work is licensed under a Creative Commons Attribution 4.0 International License.
Search Panel
- HTML viewed - 7937 times
- Download PDF downloaded - 2409 times
- View Article downloaded - 26 times