ARTICLE
Auteur(s) : Robert E Verloop1, Pieter
Koolwijk1, Anton Jan van Zonneveld2, Victor WM van
Hinsbergh1
1Laboratory for Physiology, Institute
for Cardiovascular Research, VU University Medical Center
Amsterdam, Amsterdam, The Netherlands
2Department of Nephrology
and the Einthoven Laboratory for Experimental
Vascular Medicine, Leiden University Medical Center, Leiden, The
Netherlands
accepté le 12 Juin 2009
Once the vascular tree has grown to maturity, the endothelium
remains in a rather quiescent state. However, during tissue repair
after injury, in response to tissue growth or in pathological
conditions, neovascularization occurs, often as sprouting from the
existing microvessels. In addition to this angiogenic process, it
is generally believed that vasculogenesis can also contribute to
neovascularization in the adult. This process is driven by the
recruitment of circulating endothelial progenitor cells (EPC), and
the subsequent participation of these cells in the growing vessels
[1, 2]. Asahara et al. [1] described for the first time the
isolation and characterization of EPC and their contribution to
therapeutic neovascularization in animals. This work shifted the
existing view on neovascularization, since at that time the overall
consensus was that new vessel formation, in adult life, was solely
the result of proliferation and rearrangement of mature cells of
the existing vasculature. The interest in these cells was further
stimulated by the observation that alterations in the number or
function of EPC have been associated with different manifestations
of cardiovascular disorders and atherosclerosis [3, 4]. However,
subsequent studies pointed to a limited participation of these
circulating cells in the endothelial lining of newly grown vessels
[5] and challenged the existence of EPC [6, 7].
At present, two different phenotypes of EPC have been
recognized, with predominant characteristics of either monocytic or
endothelial cells. Here, we will briefly describe the
characteristics of the different cell types that have been
indicated as EPC. Subsequently, we will discuss current insights
into the molecular mechanisms that are involved in mobilization and
recruitment of progenitor cells to areas of neovascularization,
with specific emphasis on the role of proteases and receptors.
Identity of endothelial progenitor cells
On the basis of different cell culture protocols,
immunohistochemical characterization, and flow cytometric analysis,
two different populations of EPC have been recognized. First,
myeloid EPC are obtained when mononuclear cells from cord or
peripheral blood are cultured for four to seven days in endothelial
growth media. These cells that display both myeloid and endothelial
cell markers most likely are derived from a subpopulation of
monocytes and are also referred to as early-outgrowth cells.
A second EPC population is contained in the
CD34+/CD45− cell fraction that circulates in
low numbers. Upon culture in endothelial cell growth medium for
about 14 days, a very small number of these cells can develop
into colonies of so-called late-outgrowth cells, also referred to
as endothelial colony-forming cells (ECFC) [8], or blood outgrowth
endothelial cells (BOEC) [9]. These cells display the
characteristics of mature endothelial cells, have a high
proliferative capacity, and are able to form capillary-like
structures. Both types of cells can contribute to
neovascularization, but the nature of their contribution is
different. The myeloid EPC predominantly support angiogenesis and
arteriogenesis in a paracrine fashion, whereas the late-outgrowth
cells can physically incorporate into the endothelial lining of the
new vascular structures (see also Hirschi et al. [9] and
Fadini et al. [4] for review).
Cell culture and characterization of EPC
Ideally, EPC should be characterized by a combination of a specific
set of surface antigens and functional properties that confer
specific endothelial functions to these cells. However, this goal
has only partially been achieved, due to the limited number of
cells initially available in the blood and the shift in (surface)
protein expression during the maturation of these cells. In
embryonic development, endothelial cells are derived from
CD34+, VEGFR-2+, CD133+-positive
hemangioblasts of the blood island (VEGFR-2 stands for
vascular endothelial growth factor [VEGF] receptor 2). When
hemangioblasts are exposed to VEGF, they differentiate into
CD34+VEGFR-2+ angioblasts that function as
EPC in embryonic vasculogenesis. In addition, CD34 is also
expressed on a wide range of mesoderm progeny including, blood,
endothelial, fibroblast, epithelial and some cancer cell
populations [10]. VEGFR-2 (KDR/Flk-1) was the first
endothelial marker used in the isolation of EPC [1].
Assuming circulating EC would be similar to the embryonic
angioblasts, Asahara et al. [1] plated cells enriched for
CD34+ and VEGFR-2+ on fibronectin in an
“endothelial medium”. In co-culture with CD34+-depleted
mononuclear cells, clusters with round cells centrally and sprouts
of spindle-shaped cells at the periphery appeared within three
days. These attaching cells endocytosed acetylated-LDL, stained
with Ulex europaeus lectin (UEA-1), and displayed surface
expression of endothelial markers CD31, Tie-2, E-selectin and
VEGFR-2. Later, the protocol was adopted by Ito et al. [11]
and Hill et al. [12], who cultured unselected peripheral blood
mononuclear cells (with additional re-plating selection) in
endothelial medium. Similarly, round cells centrally, with
spindle-shaped cells at the periphery appeared and were named
colony-forming unit endothelial cells (CFU-EC, also known as
CFU-Hill). This and comparable assays became very popular because
of the correlation of CFU-EC with endothelial function and
cumulative indexes of cardiovascular risk (Framingham risk factor
score) [3, 12-14]. However, from subsequent studies it became clear
that these colonies were in fact not endothelial cells, but
consisted of a core of round, hematopoietic cells, including
myeloid progenitor cells, monocytes and T lymphocytes, and
spindle-shaped monocytes/macrophages that display some features of
endothelial cells, such as CD31, CD105, CD144, CD146, vWF, VEGFR-2,
and UEA-1 [15-19]. Furthermore, proteomic analysis showed that
these colonies had been contaminated by platelet microparticles,
explaining the presence of several endothelial markers [20].
Although the CFU-EC were not composed of endothelial progeny, it
does not exclude CFU-EC from being involved in angiogenesis or
serving as a biomarker for clinical outcome in cardiovascular
diseases. Indeed, it has been shown that monocytes/macrophages are
potent circulating regulators of angiogenesis and arteriogenesis,
and play an important role in the initiation of angiogenesis during
wound healing, tissue ischemia and tissue remodeling without
actually being incorporated into the endothelial lining [21-27].
Thus, early-outgrowth cells can support angiogenesis in an indirect
manner by producing essential growth factors and cytokines, similar
to monocytes [21, 24, 27-31].
The late-outgrowth ECFC have the classical endothelial
cobblestone phenotype and display a wide range of vascular
endothelial markers, but do not express CD45, CD14, or CD115, nor
do they ingest bacteria (a monocyte/macrophage characteristic). In
comparison with the early-outgrowth CFU-EC, late-outgrowth ECFC
show exponential growth and a high proliferative capacity [8, 15,
30, 32, 33]. Furthermore, in contrast to CFU-EC, the late-outgrowth
ECFC spontaneously form blood vessels that associate with the
nearby vessels and become a part of the systemic circulation in
mice [15, 34, 35]. On the basis of these and other experiments, it
has been suggested that the late-outgrowth ECFC are derived from
circulating cells that best approximate the true “endothelial
progenitor cell” definition of EPC [9, 15, 36].
Further characterization of different types
of EPC
The antigen CD133 has been suggested as a marker of stem/progenitor
cells. Case et al. [37] and Timmermans et al. [38]
carefully studied the functional properties of isolated circulating
CD133+CD34+VEGFR-2+ cells in
hematopoietic and endothelial assays [9]. They demonstrated that
this selected population of circulating cells is highly enriched in
hematopoietic progenitor activity, but, in contrast to what was
expected at that time, does not give rise to any endothelial
colonies in vitro. In addition, more than 99% of these cells also
expressed the pan-leukocyte antigen CD45. Although the cells failed
to give rise to endothelial colonies, cells with this marker
profile (or any combination of these markers) appear to play a role
in angiogenesis in various human disease states and are predictive
biomarkers for cardiovascular disease [39-43].
In contrast to CD34+CD45+ cells, culturing
CD34+CD45− cells resulted in colonies of
highly proliferative endothelial cells [37, 38]. These endothelial
colonies expressed VEGFR-2, but not CD133. They manifested as
blood-outgrowth endothelial cells (BOEC), and likely represent the
same cell population as the late outgrowth ECFC mentioned
above.
Additional evidence for the existence of two different EPC
populations came from studies in patients with chronic
myeloproliferative disorders (CMPD) [44]. ECFC derived from CML
patients, or Ph-negative CMPD were not clonally related to the
cells that gave rise to the hematopoietic disorder. However, the
disease marker was present in all CFU-EC derived from the blood of
these patients, thus confirming that CFU-EC are derived from
myeloid cells.
From the foregoing, it is clear that a distinction between the
two populations is needed for understanding the contribution of EPC
in angiogenesis. However, as literature data on the recruitment of
EPC from the bone marrow and their contribution to angiogenesis
often fail to make this discrimination, we shall refer in the
forthcoming discussion to CFU-EC for early-outgrowth myeloid cells
that have acquired endothelial markers, and to ECFC for the few
cases where late-outgrowth progenitor cells have been used, which
have a true endothelial nature. Furthermore, we shall use EPC to
indicate the overall populations of circulating or non-defined EPC,
which de facto largely consist of CFU-EC progenitors.
Mobilization of endothelial progenitor cells from the bone
marrow
The adult bone marrow is the principal reservoir of stem and
progenitor cells, including hematopoietic and vascular precursors,
such as endothelial progenitor cells. Anatomically, two distinct
zones can be recognized in the bone marrow, the osteoblastic and
vascular zones (figure
1). In the hypoxic, osteoblastic zone, or stem cell niche,
stem cells are in close contact with stromal cells (osteoblast,
fibroblast, endothelial and reticular cells). The combined effect
of a very low oxygen tension (hypoxia) and interaction with stromal
cells preserves the maintenance and function (stemness) of
hematopoietic and vascular stem/progenitor cells [45]. Migration of
stem cells towards the vascular zone facilitates their
proliferation and differentiation, followed by the disengagement
from the bone marrow and entry into the circulation [46].
Bidirectional movement of stem cells between these two zones is
regulated by multiple signaling and adhesion molecules, which
contribute diverse characteristics to each niche’s function.
Well-studied signaling molecules involved in stem cell niche
regulation include SCF/c-Kit, Jagged/Notch, SDF-1/CXCR4, and
angiopoietin-1/Tie2 (Ang-1/Tie2) (see also Kiel et al.
[47], Blank et al. [48], and Arai et al. [49] for
review).
Proteolytic modification of receptors and cytokines
in the mobilization of progenitor cells
Proteinases play an important role in the overall process of
mobilization of progenitor cells [50]. They include serine
proteases, cysteine cathepsins, matrix metalloproteinases (MMP) and
metalloproteinases of the ADAM family. They act by receptor
activation, generation of receptor ligands, cleavage of adhesion
molecules and matrix proteins, and inactivation or modification of
cytokines. For example, after binding an activating ligand, Notch
is activated by two subsequent proteolytic events. The first,
executed by a metalloproteinase (likely ADAM-10 or -17),
releases the extracellular domain. Subsequently, at the inner side
of the plasma membrane, another protease, γ-secretase, liberates
the cytoplasmic tail of Notch, which induces further signaling in
the cell.
Following the seminal observations of Heissig et al. [51],
it became clear that MMP-9 plays a central role in the
mobilization of EPC. It was demonstrated that, after
fluorouracil-induced bone marrow ablation in mice, myelosuppression
was accompanied by elevated plasma levels of stromal cell-derived
factor-1 (SDF-1) and vascular endothelial cell growth factor
(VEGF), which upregulated the expression of MMP-9 in bone
marrow cells (both HSC and stromal cells). MMP-9 liberated
sKitL (also known as stem cell factor [SCF]) from its membrane
precursor KitL on bone marrow stromal cells. Signaling of sKitL,
through c-Kit (SCF receptor) recruited c-Kit+
stem/progenitor cells to the circulation, including
VEGFR-2+ EPC (figure 1). These
observations were underscored by experiments in MMP-9−/−
mice, which demonstrated impaired release of sKitL and HSC
motility. This deficiency resulted in impairment of hematopoietic
recovery and increased mortality after bone marrow ablation, while
exogenous sKitL restored hematopoiesis and survival. Of note, HSC,
cardiac, epithelial and EPC all express the receptor for sKitL,
c-Kit [52, 53].
Subsequent studies in endothelial nitric oxide synthase
(eNOS)-knockout mice identified nitric oxide (NO) as a crucial
cofactor in VEGF-induced MMP-9 activation [54]. Mice deficient
in eNOS showed reduced VEGF-induced mobilization of EPC (CFU-EC)
and increased mortality after myelosuppression. Mechanistically,
MMP-9 activity was reduced in the bone marrow of eNOS
-/- mice, because of reduced S-nitrosylation of MMP-9
[55]. The importance of NO in progenitor cell function was further
highlighted by the work from Sasaki et al. [56], who treated
dysfunctional bone marrow cells from ischemic cardiomyopathy (ICMP)
patients with the novel eNOS transcription enhancer AVE9488.
AVE9488 increased eNOS mRNA levels and eNOS activity, which at
least partially reversed the impaired functional activity of BMC,
improving the neovascularization capacity of infused BMC in an in
vivo, ischemic hindlimb model.
Apart from VEGF and SDF-1, which are considered to be among the
most effective mobilizers of EPC, a vast number of growth factors
and cytokines have been described to modulate mobilization of EPC
(CFU-EC) [57]. Granulocyte colony-stimulating factor (G-CSF), which
has a strong stem/progenitor cell mobilizing potential, induces the
release of elastase and cathepsin G from neutrophils, leading to
the cleavage of adhesive bonds on bone marrow stromal cells [58,
59]. Moreover, these proteases can cleave and inactivate SDF-1,
which is released by stromal cells and signals through its receptor
CXCR4 on stem/progenitor cells [59, 60]. Similarly, G-CSF
induced upregulation of the exopeptidase CD26 on
CXCR4+ stem cells. CD26 is able to splice the
N-terminal dipeptide from SDF-1, which causes inhibition of
CXCR4 activation and reduced cell retention, resulting in an
additional mechanism of mobilization [61, 62].
A role for the plasminogen activator system in the recruitment
and homing of CD34+ progenitor cells has also been
suggested. Selleri et al. [63] documented the co-mobilization
of myeloid and monocytic cells with an increased uPAR expression,
as well as the increase in serum levels of soluble uPAR and cleaved
soluble uPAR after G-CSF-induced CD34+ HSC mobilization. Both
fragments were able to attract CD34+ progenitor cells via
activation of the high-affinity fMet-Leu-Phe (fMLP) receptor (FPR)
and desensitization of the SDF-1 receptor CXCR4 (which
facilitates bone marrow retention of HSC) both in vitro and in vivo
[64]. Recently, compelling data from Tjwa et al. [65]
demonstrated that membrane-anchored uPAR is present on a
subpopulation of HSC, regulating stem cell-cycle status, adhesion
to the bone marrow microenvironment, and homing and engraftment in
vivo. During G-CSF treatment, plasmin is most likely to be
responsible for cleavage of uPAR and increased plasma levels of
soluble uPAR. The concomitant loss of the interaction of uPAR with
α4β1 integrin thereby promoted stem cell
mobilization. Similarly, impaired stem cell mobilization as well as
homing and engraftment of transplanted stem and progenitor cells
occurred in uPAR-deficient mice [65].
Mobilization of ECFC progenitors from the bone
marrow
Due to their low frequency and the incomplete characterization of
the circulating precursors of ECFC, there is no information
available at present on the origin and mobilization of cells that
form the ECFC. It seems plausible these cells already develop into
an endothelial cell lineage in the bone marrow, in a process that
requires VEGF and Notch signaling [66, 67], and that their
recruitment to the vascular niche of the bone marrow proceeds in a
way comparable to that used by other progenitor cells.
Homing of EPC to areas
of neovascularization
Recruitment of EPC to sites of neovascularization or endothelial
injury strongly resembles that of an inflammatory response. Once in
the vicinity of an injured vessel, EPC can interact with activated
platelets, the damaged endothelial monolayer and components of the
sub-endothelial matrix. This process has many similarities with the
homing of leukocytes to the activated endothelium. This should not
be surprising, given that all studies on the homing of EPC have
been done with cells that are CFU-EC, and therefore largely, if not
exclusively, myeloid in nature.
Homing and incorporation of EPC in the endothelial lining or
sub-endothelial space is a multi-step process, which involves
chemo-attraction, rolling and tethering of progenitor cells,
subsequent firm adhesion and, finally, extravasation (figure 2). Various degrees
of blood vessel and tissue injury may result in the production and
release of cytokines and chemokines creating a gradient within the
vessel wall. A large number of cytokines and growth factors,
including VEGF [24, 68, 69], insulin-like growth factor 2 (IGF2)
[70], monocyte chemotactic protein 1 (MCP-1/CCL2) [71],
interleukin-8, CXCL1 and CXCL7 [72, 73], bradykinin [74],
macrophage migration inhibitory factor (MIF) [75], and
SDF-1/CXCL12 have been described as participating in EPC
(CFU-EC) recruitment.
The latter one, SDF-1, and its specific receptor CXCR4 play a
major role in stem cell recruitment and retention to ischemic areas
[76-78]. In physiological conditions, SDF-1 is constitutively
expressed, but a range of stimuli such as inflammation [79], tissue
damage and hypoxia rapidly increase SDF-1 levels.
SDF-1 is expressed or is surface-bound at injured smooth
muscle and endothelial cells, and is released by activated
platelets [80-83]. Activated platelets secrete high levels of
SDF-1. Platelets are probably the first responders to vascular
trauma and, after their adherence to subendothelial matrix
structures and subsequent activation, release the necessary factors
for progenitor cell mobilization and homing to the damaged area
[81]. Reduced tissue and plasma levels of SDF-1 have been
correlated with unstable coronary artery disease [84] and impaired
wound healing in diabetes [85]. The gene expression of
SDF-1 is regulated by the transcription factor
hypoxia-inducible factor-1α (HIF-1α) and is also induced by VEGF
overexpression, thus mediating SDF-1-dependent recruitment of
CXCR4+ progenitor cells to injured arteries and hypoxic
regions [24, 86, 87].
As with the impaired SDF-1/CXCR4 signaling in diabetic
patients, Kränkel et al. [74], reported that circulating
progenitor cells from cardiovascular disease patients showed low
levels of the kinin B2 receptor (B2R) and decreased migratory
capacity toward bradykinin (BK), suggesting that impaired homing
and migration might contribute to impaired neovascularization after
ischemic complications.
Retention of CD34+ progenitor cells
by developing endothelial tubes in vitro
The interaction of EPC with capillary-like endothelial tubes can be
mimicked in vitro in a three-dimensional fibrin-based tube
formation assay [88]. We applied time-lapse video microscopy to
study the movement (chemokinesis) of peripheral and cord
blood-derived CD34+ progenitor cells and the selective
homing towards sites of tube formation (chemotaxis). The formation
of tubes by human microvascular endothelial cells in a fibrin
matrix was induced by addition of VEGF/TNF-α or bFGF/TNF-α (figure 3).
Subsequently, the CD34+ progenitor cells were placed on
top of the fibrin matrix covered with endothelial cells, which had
started to form tubular structures. The CD34+ cells
displayed a random movement over the stimulated endothelial
monolayer during an 8-hour observation period. However, once the
CD34+ cells reached a tubular structure they remained
associated with that structure, either moving around in the tubule,
or silently trapped. Quantification of these data (table 1) showed that 80% of the cells that reached
a tubular area were trapped, while in comparable control areas only
5% was present. Furthermore, the CD34+ cells entered a
tube area as frequently as control areas of the same size and
shape, suggesting chemokinesis rather than chemotaxis. However, one
should note that the presence of serum, which contains large
amounts of SDF-1, likely interfered with SDF-1-induced chemotaxis.
When the CD34+ cells were fixed with paraformaldehyde
before adding them to the tube formation system, a complete arrest
of the administered CD34+ cells on the stimulated
endothelial monolayer was observed, indicating that the movement
was indeed an active process of the cells. In contrast, fixation of
the endothelial monolayer and tubular structures interfered neither
with the random movement of the CD34+ cells, nor with
the accumulation of CD34+ cells at the tubular
structures. The response to fixed tube structures and the absence
of a chemotactic response suggest that adhesion receptors rather
than cytokines were involved. Preincubation of the endothelial
monolayer with a cocktail of blocking antibodies against E- and
P-selectin, ICAM-1 and VCAM-1 to study this process was
not sufficient to block the accumulation of CD34+ cells
at the tubular structures, suggesting that other adhesion factors
may also be involved.
Table 1 Migration and tubular homing of peripheral and
cord blood CD34+ cells
|
Source of CD34+
|
Stimulus for endothelial tube formation
|
Area studied
|
Entering/leaving CD34+ cells
|
CD34+ retention (%)
|
|
Donor 1
|
Donor 2
|
|
PB-CD34+
|
VEGF + TNF-α
|
Tubular structures
|
123/59
|
47/18
|
52.0-61.7%
|
|
Control monolayer
|
83/71
|
47/42
|
10.6-14.5%
|
|
CB-CD34+
|
bFGF + TNF-α
|
Tubular structures
|
21/5
|
47/17
|
63.8-76.2%
|
|
Control monolayer
|
29/28
|
37/34
|
2.3-8.1%
|
|
CB-CD34+
|
VEGF + TNF-α
|
Tubular structures
|
41/8
|
71/12
|
80.5-83.1%
|
|
Control monolayer
|
51/48
|
45/39
|
5.9-13.3%
|
|
CB-CD34+ on fixated tube assay
|
VEGF + TNF-α
|
Tubular structures
|
|
54/5
|
90.70%
|
|
Control monolayer
|
|
21/19
|
9.50%
|
|
Fixated CB-CD34
|
VEGF + TNF-α
|
Tubular structures
|
|
0/0
|
0/0*
|
|
Control monolayer
|
|
0/0
|
0/0*
|
Receptors involved in EPC (CFU-EC) homing to areas
of angiogenesis in vivo
The initial adhesion of EPC (CFU-EC) seems to be mediated by
injury/ischemia-induced upregulation of E- and P-selectin.
A number of reports describe the expression analysis and in
vivo blocking of P- and E-selectin, thereby attenuating the
interaction with P-selectin glycoprotein ligand-1 (PSGL-1) on
EPC (CFU-EC) [89]. Treating E-selectin-deficient mice with soluble
E-selectin (sE-selectin) enhanced the efficacy of EPC
transplantation to induce neovascularization and salvage of the
ischemic limb. Conversely, when E-selectin was knocked down by
E-selectin small interfering RNA (siRNA), blood flow recovery after
EPC transplantation was significantly impaired. The beneficial
contribution of sE-selectin was further enhanced by stimulating
ICAM-1 expression on endothelial cells [90]. In addition,
Foubert et al. [91] demonstrated that PSGL-1 expression
on EPC was regulated by ephrin receptors and their ligands, key
regulators in vascular development. EphB4 receptor activation
with an ephrin-B2-Fc chimeric protein increased the angiogenic
potential of human EPC in a nude mouse model of hindlimb ischemia,
by induction of PSGL-1 and adhesion to E-selectin and
P-selectin. In the case of more severe injury, when subendothelial
matrix components are exposed, activated platelets and coagulation
factors (fibrin) rapidly produce a microenvironment facilitating
PSGL-1-mediated adhesion of CD34+ progenitor cells [73,
83, 92].
Integrins expressed on the surface of EPC mediate the firm
adhesion and transmigration of EPC to the damaged endothelium.
Again, the murine model of hindlimb ischemia was utilized to
demonstrate that progenitor cells from
β2-integrin-deficient mice are less capable of homing to
sites of ischemia and of improving neovascularization.
Preactivation of the β2-integrins expressed on EPC by
activating antibodies augments the EPC-induced neovascularization
in vivo [93]. This work was supported by the fact that not only
VLA-4 (α4β1 integrin) and
LFA-1 (αLβ2 integrin), but also their
counterparts ICAM-1 and VCAM-1, were upregulated in ischemic
tissue [94-96]. Neutralization of one of these factors reduced
adhesion and migration of EPC in vitro and reduced recovery of
hindlimb blood flow, capillary density and incorporation of EPC
into ischemic tissues in vivo [96-98]. Mechanistically, cell
adhesion molecule (CAM)-integrin-mediated firm adhesion was
reported as being regulated by hypoxia as well as necrosis.
High-mobility group box 1 (HMGB1) is a nuclear protein that is
released extracellularly upon cell necrosis and tissue damage.
Binding of HMGB1 to its receptor RAGE (receptor for advanced
glycation end products) on EPC resulted in rapidly increased
integrin affinity and induced integrin polarization, enhancing the
in vitro adhesion and migration and in vivo homing and
incorporation of EPC in the tumor vasculature [99].
Exposure of endothelial cells to hypoxia increased the
endogenous amount and kinase activity of the protein
integrin-linked kinase (ILK-1) in a NFκB- and HIF-1α-dependent
manner. Overexpression of ILK-1 resulted in
ICAM-1 upregulation, whereas blocking ILK-1 abrogated the
expression of ICAM-1 under hypoxia, with co-committed
reduction in EPC homing and poor neovascularization in vivo [100,
101]. In addition, the adipokine leptin, a published modulator of
vascular remodeling and neointima formation, has recently been
described as increasing the expression of
αVβ5- and α4-integrins in EPC
[102].
Proteases involved in homing of EPC (CFU-EC)
Transmigration of EPC into the injured or hypoxic tissue is the
last step of homing and recruitment of progenitor cells to the area
of angiogenesis. The invasive capacity is crucial for tissue repair
and restoration of organ function [103], stressing the importance
of protease production and release by EPC. EPC and EPC-derived
cells express various cysteine cathepsins, MMP, and u-PA and the
receptor uPAR [63, 104-106].
Urbich et al. [104] demonstrated the crucial role of
cathepsin L in EPC-mediated neovascularization. Cathepsin L was
highly expressed in EPC and was essential for matrix degradation
and invasion by EPC in vitro. Cathepsin L-deficient mice showed
impaired functional recovery following hindlimb ischemia. Infused
cathepsin L-deficient progenitor cells neither homed to sites of
ischemia nor augmented neovascularization. This could be reversed
by forced expression of cathepsin L in mature endothelial cells.
Recently, the same group revealed a decreased cathepsin L
expression and activity in EPC from patients with type
2 diabetes, suggesting a novel mechanism for diabetes-related
impairment of neovascularization [107].
Membrane-type-(MT-)1-MMP (MMP-14) is another powerful protease
involved in migration and invasion of cells including
CD34+ progenitor cells [106]. Recently, it was shown
that the balance between the expression of MT1-MMP and its
membrane-anchored inhibitor RECK [108], is involved in the
regulation of homing, retention, egression, and mobilization of
immature human CD34+ progenitor cells [109].
Steady-state egression of human CD34+ cells and, to a
greater extent, their G-CSF-induced mobilization, is accompanied by
an increase in MT1-MMP and a simultaneous reduction in RECK
expression, which facilitate MT1-MMP-mediated CD44 cleavage
and progenitor cell motility and mobilization. Furthermore,
MMP-2 was found to affect the invasive properties of EPC.
MMP-2−/− mice responded poorly to hindlimb ischemia
because of reduced neovascularization. Transplantation of
MMP-2+/+ bone marrow cells dramatically improved the
recovery of these mice [110]. Stimulation with TNFα, IL-8 or
SDF-1 resulted in increased MMP levels, facilitating the
migration of EPC into Matrigel plugs or transwell systems [36,
111-113].
Finally, a role for the plasminogen system in EPC homing and
recruitment was anticipated. Xiang et al. [114] investigated
the potential of the plasminogen system in vivo. Blocking the
protease inhibitor plasminogen-activator inhibitor-1 (PAI-1)
with a sequence-specific DNA enzyme at the time of myocardial
infarction, resulted in increased engraftment of exogenously
delivered CD34+ progenitors in the infarct zone.
Abrogation of the natural inhibition of PAI-1 on u-PA was most
likely responsible for the observed effect [114].
Homing of ECFC progenitors
The circulating progenitors of ECFC are probably cells that can be
recruited to areas of neovascularization and tissue repair. Their
endothelial nature makes direct interaction and incorporation into
the endothelial lining possible. However, one would expect that the
circulating counterpart of ECFC must be able to recognize an area
in need of (neo)vascularisation support, and to home to and migrate
into it. Recent studies have suggested that the combination of
CFU-EC and ECFC was more effective in stimulating
neovascularization and tissue repair, and also pointed to a
directed influx and action of the ECFC [36, 115], although this
issue remains controversial.
While no information is presently available on homing receptors,
it is likely that these cells use similar proteases as other
endothelial cells, such as MT1-MMP, MMP-2, MMP-9 and the
urokinase/plasmin system [116]. These proteases are indeed
expressed in ECFC. Cultured ECFC displayed relatively high u-PA and
MMP-2 levels compared to normal endothelial cells [105, 117].
Inhibition of ECFC-associated u-PA by monoclonal antibodies that
block u-PA activity or binding to its receptor significantly
reduced proliferation, migration and capillary-like tube formation
in vitro [105, 117].
Participation of EPC in the newly formed
vessels
A number of studies using various animal models have suggested that
bone marrow-derived and circulating progenitor cells are capable of
repopulating within damaged organs, possibly contributing to
angiogenesis (see Tanaka et al. [118], and Zampetaki
et al. [103] for review). However, the contribution of bone
marrow-derived EPC to neovascularization has been seriously
challenged by other groups, who found no evidence for such a
process in tumor vascularization in mice [6, 7]. Differences in the
evaluation at early and late time points, reflecting a contribution
in the initial phase only, and the fact that the ECFC are so few
that they are not easily encountered in mice, may, in part, explain
these differences [119]. If EPC and ECFC contribute to angiogenesis
and/or vasculogenesis, they might do so at three levels. Firstly,
they can provide growth factors or other signals that stimulate and
orchestrate the angiogenesis process. Secondly, ECFC can enforce
the endothelial lining of preexisting and newly formed vessels by
being incorporated in the endothelial lining (intussusception).
Finally, ECFC can organize themselves into new vascular structures
that connect to the resident circulation.
Intussusception of circulating EPC in healing human
blood vessels
The extent to which endothelial progenitors contribute to human
angiogenesis and vascular maintenance is still a matter of
controversy [120, 121]. The identification of gender- or
HLA-mismatched cells in (injured) tissue after transplantation of
solid organs or bone marrow has been used in various studies as an
indicator of the intussusception of circulating cells in a vascular
bed. In an early study, Hruban et al. [122] detected cells of
recipient origin in allografted hearts following cardiac
transplantation. At that time, endothelial cells of recipient
origin had not been identified in allografted hearts, apart from a
rare number of flattened cells lining the vascular lumens.
Additional immunohistochemical analysis revealed that these cells
were in fact macrophages [122]. Indeed, after damage of the
vasculature, monocytes can spread over the exposed vessel matrix,
an initial coverage that later can be replaced by endothelial
cells. More decisive was a small but significant number of reports
based on sex-mismatched bone marrow transplantations, which
suggested that human bone marrow-derived EPC incorporate into tumor
vessels [5, 123], skin [124], endometrium [125] and transplanted
hearts and livers [126-130]. In all these studies, only very low
numbers of cells (usually less than 1-5%) were encountered in the
endothelial lining of healthy, small blood vessels. Vascular
injury, as occurs at sites of atherosclerotic plaque development,
or after myocardial infarction, increased the number of
incorporated bone marrow-derived cells to a various degree [127,
130]. A time-course of endocardial biopsies demonstrated that
there was neither an increase nor a decrease in the number of
incorporated cells over a 10-year period [129].
Contribution of late-outgrowth ECFC, but not early
EPC to endothelial tubular structures
In vitro studies on endothelial tube formation have shown that the
contribution of classical EPC, the early-outgrowth cells that
mainly reflect myeloid cells, and late-outgrowth ECFC, are
different. The classical early EPC (CFU-EC) associate with the
newly forming microvessels, but show little incorporation into the
endothelial lining, nor are they able to form tubes by themselves
[15, 30-32, 131]. Instead, they can stimulate and possibly shape
the growth of new vessels. CFU-EC act by releasing angiogenic
growth factors, and possibly by cellular contact. Therefore, they
can be considered as angiogenic accessory cells.
In contrast, the ECFC incorporate into existing differentiated
endothelial tubule structures in vitro, and are also able to form
tubules readily, by themselves [15, 34, 117, 131]. This process
proceeds similarly as the tube formation by microvascular
endothelial cells, and depends on proper integrin-matrix
interactions and the pericellular recruitment of proteases,
including u-PA, the metalloproteinases MT1-MMP and MMP-2, and
cathepsin L [104, 105, 117].
More convincingly as regards clinical applications, several
reports have also shown that peripheral blood- and cord
blood-derived ECFC can form functional blood vessels when implanted
in vivo [15, 34, 132]. This opens avenues for the engineering of
new vasculature in tissues with limited blood supply. However, Au
et al. [133] reported that umbilical cord blood-derived ECFC,
when co-transplanted with mesenchymal cells in mice, formed stable
vascular structures, while similar cells obtained from peripheral
blood formed only a limited number of unstable vascular structures.
Thus, ECFC are able to participate in blood vessels as true
endothelial cells, but much has still to be learned about their
prerequisites and functional properties.
Conclusion
A number of clinical conditions requires an enforcement of the
endothelial lining of blood vessels, either because cell
replacement is needed due to endothelial injury or apoptosis, or to
keep up with the expansion of the endothelial lining during
neovascularization. The concept of an EPC that can differentiate
into a true endothelial cell with high proliferation potential is
attractive, but also hotly debated and more complex than originally
anticipated. As discussed above, EPC can be recruited, in
particular by stimuli induced by hypoxia, to areas of tissue repair
and neovascularization, and participate directly or indirectly in
the growth of the new vasculature. However, our understanding of
the true nature of these progenitor cells is rather fragmented.
Different types of cells, which were originally recognized as EPC,
reflect neovascularization-supporting cells with different
functions and background. Two populations have currently been
identified, but the existence and the contribution of other small
populations within the blood-derived inoculum, and additional
functions, cannot be excluded.
The first population involves the early-outgrowth EPC (CFU-EC),
which have a myeloid origin. They represent monocytes with
endothelial properties and a strong ability to provide factors to
stimulate angiogenesis, but little capacity to incorporate
persistently into the endothelial lining. The decrease in
circulating EPC observed in diabetes and cardiovascular disease may
reflect a contribution to vascular maintenance and repair in
patients, but alternatively may merely reflect increased oxidative
stress [134]. Future studies will clarify whether these cells
reflect the course of the disease, making them suitable as a
prognostic marker, or whether their reduction also contributes to
the etiology of the vascular complications (causal), thus providing
a perspective on new therapies.
The second population (ECFC or late-outgrowth EPC) grows out as
colonies of real endothelial cells. Better identification of these
cells in the blood by specific markers would help to improve the
isolation, separation and amplification of these cells, and the
possible use of these cells for autologous and possibly
heterologous transplantation. Much has still to be learned; it may
well be that these cells perform best in collaboration with other
mesenchymal cells. Furthermore, the differences between ECFC
obtained from cord blood and those from peripheral blood require
further attention.
The mobilization and recruitment of the progenitor cells that
develop into the myeloid CFU-EC and endothelial ECFC is determined
in the bone marrow and formation of similar new interactions at the
sites of homing and neovascularization. Proteases, such as MMP-9,
play an important role in mobilization from the bone marrow by
disintegration of existing cell adhesions and chemokine-receptor
interactions. Once liberated, the circulating progenitor cells home
via receptors that act as cell adhesion molecules and recognize
cytokine gradients, such as SDF-1 in hypoxic areas. The
subsequent invasion process requires proteolytic activity to
squeeze the cells through the collagen-rich extracellular matrix
and/or the fibrin matrix of a fibrinous exudate. In this latter
process, MT1-MMP, MMP-2 and u-PA acting on a cellular uPA
receptor are involved. Indeed, cultured ECFC have a high expression
of u-PA, which appears to be involved in migration and tubule
formation. Similarly roles for MT1-MMP, MMP-2 and cathepsin L
are likely. Furthermore, these and other proteases also activate
and modify cytokines, angiogenic growth factors and their
receptors, thus fine-tuning the regulation of the
neovascularization process.
Acknowledgments
This work was supported by grants of STW/DPTE (grants VGT 67.47 and
LGT.69.18), and the Netherlands Heart Foundation (grant nr
2002B157).
Disclosure. The authors have no conflicts of interest to
declare.
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