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J Biol Chem, Vol. 274, Issue 43, 30361-30364, October 22, 1999
§¶,§,,
,**, and
From the Institut für Prophylaxe und
Epidemiologie der Kreislaufkrankheiten, Universität
München, Pettenkoferstrasse 9, 80336 München, Germany,
the ** Max-von-Pettenkofer-Institut für Medizinische
Mikrobiologie, Pettenkoferstrasse 9a, 80336 München, Germany,
and the Department of Biochemistry, Cardiovascular Research
Institute, University of Maastricht, P. O. Box 616, 6200 MD Maastricht, The Netherlands
 |
ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Mildly oxidized low density lipoprotein
(mox-LDL) is critically involved in the early atherogenic responses of
the endothelium and increases endothelial permeability through an
unknown signal pathway. Here we show that (i) exposure of confluent
human endothelial cells (HUVEC) to mox-LDL but not to native LDL
induces the formation of actin stress fibers and intercellular gaps
within minutes, leading to an increase in endothelial permeability;
(ii) mox-LDL induces a transient decrease in myosin light chain (MLC)
phosphatase that is paralleled by an increase in MLC phosphorylation;
(iii) phosphorylated MLC stimulated by mox-LDL is incorporated into stress fibers; (iv) cytoskeletal rearrangements and MLC phosphorylation are inhibited by C3 transferase from Clostridium botulinum,
a specific Rho inhibitor, and Y-27632, an inhibitor of Rho kinase; and
(v) mox-LDL does not increase intracellular Ca2+
concentration. Our data indicate that mox-LDL induces endothelial cell
contraction through activation of Rho and its effector Rho kinase which
inhibits MLC phosphatase and phosphorylates MLC. We suggest that
inhibition of this novel cell signaling pathway of mox-LDL could be
relevant for the prevention of atherosclerosis.
The response to injury hypothesis of atherosclerosis proposes that
the first step in atherogenesis is an endothelial dysfunction induced
by stimuli such as mildly oxidized LDL
(mox-LDL)1 (1). Vascular
endothelium exposed to oxidized LDL in vitro and in
vivo shows an increased permeability (2, 3), a hallmark of
endothelial dysfunction. The signal pathways by which mox-LDL and
oxidized LDL reduce endothelial barrier function are unknown. Confluent
endothelial cells challenged with vasoactive substances, such as
thrombin, show a rapid reorganization of their actin cytoskeleton, i.e. stimulation of myosin light chain (MLC) phosphorylation
and actin stress fiber formation, leading to cell contraction and intercellular gaps (4, 5). Such cytoskeletal rearrangements reduce
endothelial barrier function (6) and are typically found in
vivo in endothelium overlying early atherosclerotic lesions (7).
Thrombin induces endothelial cell contraction and increased endothelial
permeability through binding to a serpentine receptor which is coupled
via heterotrimeric G-proteins of the Gq family to phospholipase C This study was aimed to investigate whether mox-LDL would mimic the
action of vasoactive substances on human endothelial cells. We found
that (i) mildly oxidized LDL induced a rapid reorganization of the
actin cytoskeleton, the formation of intercellular gaps, and the
stimulation of MLC phosphorylation within minutes and (ii) that mox-LDL
induced these changes through stimulation of the Rho/Rho kinase pathway
with the subsequent inhibition of MLC phosphatase and without
increasing the cytosolic Ca2+ concentration.
Materials--
Rho kinase inhibitor Y-27632 was kindly provided
by Yoshitomi Pharmaceuticals, 3-7-25 Koyata, Iruma-Shi Saitama, Japan.
Anti-phospho-MLC antibody was a generous gift from Dr. James Staddon,
EISAI Co., London, UK. All other materials not further specified were
from Sigma, Deisenhofen, Germany.
Cell Culture--
Human umbilical vein endothelial cells (HUVEC)
were obtained and cultured as described previously (5). Before exposure to mox-LDL or native LDL, cells were serum deprived for 15 min. Medium
was then replaced by fresh serum-free medium containing mox-LDL or
native LDL as indicated.
Immunofluorescence--
HUVEC were stained for I-actin as
described previously (5). For staining of phosphorylated MLC, cells
were fixed in 3.7% formaldehyde solution in PBS and permeabilized for
5 min with 0.1% Triton X-100. Cells were treated with normal goat
serum (1/10 in PBS) for 20 min and then incubated for 1 h with
anti-phospho-MLC antibody, diluted 1/10 in PBS, followed by 1 h
incubation with rhodamine-labeled goat anti-rabbit IgG antibody
(Dianova, Hamburg, Germany), diluted 1/200 in PBS.
Myosin Light Chain Phosphorylation--
MLC phosphorylation was
analyzed by SDS-PAGE and Western blotting. HUVEC were grown for 10 days
in Costar 6-well culture dishes and treated with mox-LDL as indicated.
Cells were lysed with boiling Laemmli buffer. Proteins were then
electroblotted onto polyvinylidene difluoride membranes. Membranes were
incubated overnight with anti-phospho-MLC antibody (1/500) in
Tris-buffered saline containing 0.05% Tween 20, washed three times,
incubated for 1 h with horseradish peroxidase-labeled goat
anti-rabbit IgG antibody (Amersham Pharmacia Biotech), 1/7500 in
Tris-buffered saline, washed three times, and then developed with
Luminol solution (Pierce) and exposed to Kodak X-Omat films. The amount
of phosphorylated MLC was determined by densitometric analysis of the
protein bands that reacted with anti-phospho-MLC antibody, using a
Sharp XL-325 densitometer and Amersham Pharmacia Biotech Image Master
software. Phosphorylated MLC appeared as a single band of 20 kDa. This
20-kDa band was also detected by a mouse monoclonal antibody to total
MLC (Sigma, Deisenhofen, Germany). The lower band is because of an
unspecific reaction of the secondary anti-rabbit antibody. The range of
linearity of the densitometric measurements of phosphorylated myosin
was determined by a dilution series of protein samples of
mox-LDL-stimulated HUVEC (4-40 µg of protein/lane).
MLC Phosphatase Measurement--
For MLC phosphatase
measurement, HUVEC were activated and lysed as described (5). To
determine MLC phosphatase activity, we used smooth muscle
[ Preparation of Mox-LDL--
LDL was isolated in the continuous
presence of EDTA (18). LDL was dialyzed at 4 °C using a
N2-saturated buffer (18) containing EDTA (1 mM)
and then stored at 4 °C in darkness under N2. Mox-LDL was prepared from EDTA-free LDL by Cu2+-triggered oxidation
as described (18). Briefly, freshly dialyzed LDL containing 1 mmol/liter EDTA was loaded onto Econo-PacI0 DG columns (Bio-Rad) and
recovered in PBS. LDL was then concentrated to a final concentration of
20 mg/ml by centricon-100 concentrators (Amicon) and mildly oxidized by
incubation with CuSO4 (final concentration 640 µmol/liter) for 20 h at 37 °C. The endotoxin concentrations in mox-LDL and native LDL were determined by a Limulus assay and were 5 ng/ml of medium for native LDL and 3.7 ng/ml of medium for mox-LDL.
These endotoxin concentrations have no effects on MLC phosphorylation
or the actin cytoskeleton of HUVEC within minutes (data not shown).
Ca2+ Measurement--
Calcium measurements and
calculation of cytosolic Ca2+-concentrations of individual
cells were carried out with a Quanticell fluorimetric system (Applied
Imaging Corp., Sunderland, UK) as described (19).
Measurement of Endothelial Permeability--
Horseradish
peroxidase (HRP) diffusion through HUVEC monolayers was determined as
described previously with some modifications (5). HUVEC were cultured
for 10 days on collagen-coated cell culture inserts (3-µm pore size,
Becton Dickinson) with medium changes every 2 days. For exposure to
mox-LDL or native LDL, medium was replaced with 500 µl of culture
medium containing mox-LDL or native LDL. For controls mox-LDL was
omitted, but otherwise cells were treated identically. After 2 min of
stimulation, 500 µl of medium was filled into the lower compartment,
and the medium in the upper compartment was replaced with fresh medium
containing HRP (0.34 mg/ml, IV-A-type, Mr
44,000, Sigma, Deisenhofen, Germany). After 1 min, 60 µl of medium
was collected from the lower compartment and mixed with 860 µl of
reaction buffer (50 mM NaH2PO4, 5 mM Guaiacol) and 100 µl of freshly made
H2O2 solution (0.6 mM in H2O). The reaction was allowed to proceed for 15 min at
room temperature and absorbance was measured at 470 nm.
Mox-LDL Stimulates Actin Stress Fiber Formation via Rho/Rho
Kinase--
As shown in Fig. 1, exposure
of confluent endothelial monolayers to mox-LDL (250 µg/ml) for 2 min
changed their cobblestone morphology with a polygonal cell shape and a
dense peripheral actin ring to a contracted phenotype with rounded
cells, prominent actin stress fibers, and intercellular gaps (Fig.
1b). To test whether mox-LDL induces actin stress fibers and
cell contraction via Rho and Rho kinase, we stained control cells or
cells stimulated with mox-LDL for F-actin using rhodamine-phalloidin.
As indicated by Fig. 1a, control cells showed a dense
peripheral actin ring and almost no stress fibers. Endothelial cells
stimulated with mox-LDL (2 min, 250 µg/ml) showed prominent actin
stress fibers and a contracted phenotype with intercellular gaps (Fig.
1b). To investigate whether these actin rearrangements are
because of activation of Rho/Rho kinase, we pretreated cells with the selective Rho-inhibitor C3 transferase from Clostridium
botulinum (24 h, 5 µg/ml) or the Rho kinase inhibitor Y-27632
(30 min, 10 µM) and then stimulated the cells with
mox-LDL. C3 transferase (Fig. 1c) or Y-27632 (Fig.
1e) did not influence the actin distribution in unstimulated
HUVEC, but C3 transferase (Fig. 1d) and Y-27632 (Fig.
1f) completely blocked the mox-LDL-induced actin stress fiber formation and cell contraction, indicating that mox-LDL induced
these cytoskeletal rearrangements through activation of Rho and Rho
kinase. In contrast to mox-LDL, native LDL had no effect on the actin
cytoskeleton in human endothelial cells (Fig. 1g).
Mox-LDL Induces an Increase in Endothelial Permeability That Is
Mediated by Rho/Rho Kinase--
Endothelial cell contraction and
intercellular gap formation are expected to increase endothelial
permeability. Indeed in our experimental setting, mox-LDL (2 min, 250 µg/ml), but not native LDL, markedly increased transendothelial
diffusion of horseradish peroxidase (Fig.
2). Pretreatment of cells with C3
transferase (24 h, 5 µg/ml) or Y-27632 (30 min, 10 µM)
blocked the mox-LDL-induced increase in permeability. These findings
suggest that activation of Rho/Rho kinase is critically involved in
mox-LDL-induced increase in endothelial permeability.
Mox-LDL Inactivates MLC Phosphatase and Enhances MLC
Phosphorylation in Human Endothelial Cells--
Phosphorylation of the
light chain enables myosin to interact with and to slide against
F-actin filaments in stress fibers, which are considered the
contractile organelles of non-muscle cells such as endothelial cells
(9). If in fact mox-LDL stimulates Rho/Rho kinase, this should lead to
inhibition of MLC phosphatase followed by MLC phosphorylation (5).
Indeed, MLC phosphatase activity was found to be rapidly reduced to
about 60% of the basal activity between 30 s and 2 min of mox-LDL
treatment, which was followed by a return to base-line values after 5 min (Fig. 3a). To determine
the corresponding levels of phosphorylated MLC, we performed Western
blots using a phospho-MLC specific antibody. Fig. 3b shows a
time course of MLC phosphorylation in endothelial cells stimulated with
mox-LDL. MLC phosphorylation rose to a peak within 2 min of stimulation
and then fell to base-line levels within 15 min. In contrast to
mox-LDL, native LDL did not induce MLC phosphorylation in HUVEC. To
demonstrate that the mox-LDL-induced MLC phosphorylation is because of
Rho/Rho kinase activation, we pretreated HUVEC with C3 transferase (24 h, 5 µg/ml) or Y-27632 (30 min, 10 µM). The results
presented in Fig. 4 demonstrate that inhibition of Rho or Rho kinase completely blocked mox-LDL-induced MLC
phosphorylation. To investigate the intracellular distribution of
phosphorylated MLC in HUVEC after mox-LDL stimulation, cells were
stained for phosphorylated MLC. Fig.
5a indicates that in control
cells almost no phosphorylated MLC can be detected. In HUVEC treated
with mox-LDL (2 min, 250 µg/ml), phosphorylated MLC could be detected
that was organized in stress fibers (Fig. 5b). In cells
pretreated with C3 transferase (Fig. 5c) or with Y-27632
(Fig. 5d), no incorporation of phosphorylated MLC into stress fibers could be observed. Incubation of cells with native LDL
did not induce myosin phosphorylation (Fig. 5e).
Mox-LDL Does Not Increase Cytosolic Ca2+
Concentration--
To study whether an increase in cytosolic
Ca2+ concentration and subsequent MLCK activation also
contributes to the mox-LDL-induced MLC phosphorylation, we measured
cytosolic Ca2+ concentrations. Fig.
6 indicates that mox-LDL does not
increase cytosolic Ca2+ concentration in HUVEC indicating
that it enhances MLC phosphorylation in HUVEC mainly through the
Rho/Rho kinase pathway.
Here we describe a novel signal pathway of mox-LDL in human
endothelial cells. Mox-LDL induces cell contraction, i.e.
formation of actin stress fibers and intercellular gaps, leading to an
increase in endothelial permeability, through activation of the Rho/Rho kinase pathway. This mechanism potentially contributes to endothelial dysfunction in early atherosclerotic lesions. Down-regulation of MLC
phosphatase could also be a mechanism by which mox-LDL enhances the
effects of Ca2+-mobilizing vasoactive substances.
Conceivably, continuous stimulation of the vascular endothelium by
subendothelial mox-LDL may eventually lead to an enhanced
susceptibility of the endothelium to such vasoactive substances.
Our data indicate that mox-LDL utilizes physiologic signal
mechanisms to activate the endothelium. Although we have not determined in the present study the mox-LDL-stimulated signal pathways upstream of
Rho, we suggest that mox-LDL stimulates the Rho/Rho kinase pathway in
endothelial cells through activation of heterotrimeric G-protein-coupled receptors such as the lysophosphatidic acid (LPA)
receptor. We have indeed recently found that LPA is formed during mild
oxidation of LDL in the absence of cells and that LPA was the main
ingredient in mox-LDL responsible for the induction of platelet shape
change and endothelial cell activation (21). In fibroblasts, LPA
induces Rho-dependent stress fiber formation through
activation of G13 (22) and enhances contractility by this
way (23).
Activation of Rho and Rho kinase by mox-LDL may not be restricted to
endothelial cells. It is likely that mox-LDL activates the same pathway
in smooth muscle cells and fibroblasts. Indeed, it is well documented
that Rho kinase plays a pivotal role for Ca2+ sensitization
of vascular smooth muscle cells. Furthermore mox-LDL was found to
induce vascular smooth muscle cell contraction (24). Hence mox-LDL
could contribute to elevated levels of blood pressure by activation of
Rho kinase and thereby enhanced contractility of smooth muscle cells.
Indeed, the Rho kinase inhibitor Y-27632 has previously been found to
reduce the blood pressure in hypertensive rats (25).
In conclusion, we propose that the Rho/Rho kinase pathway is
critical for the activation of endothelial cells by mox-LDL and could
be a new target to prevent atherogenesis and cardiovascular disease.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
to
yield inositol 1,4,5-trisphosphate, which mobilizes Ca2+
from intracellular stores and thus increases cytosolic Ca2+
concentration (8). This increase in intracellular Ca2+
concentration leads to activation of
Ca2+/calmodulin-dependent myosin light chain
kinase (MLCK), which phosphorylates Thr-18 and Ser-19 of the MLC of
myosin II to enable actin-myosin interaction and cell contraction (9).
We and others recently found an additional pathway by which thrombin
regulates endothelial cell contraction. Thrombin, probably through
coupling of the thrombin receptor to heterotrimeric G-proteins of the
G12/13 family (10), was shown to activate the Ras-related
GTPase Rho and its effector p160 Rho kinase in endothelial cells (5). Rho kinase phosphorylates myosin binding subunit of MLC phosphatase which is thereby inactivated (11-13). Indeed, we observed that thrombin transiently inactivated MLC phosphatase in human endothelial cells and that phosphatase inactivation correlated with peak levels in
MLC phosphorylation. Hence, the Rho/Rho kinase pathway seems to
regulate endothelial contractility in concert with
Ca2+/calmodulin-dependent MLCK. A similar
regulatory system was reported in smooth muscle cells (14-16).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]MLC as a substrate as described previously with
some modifications (17). Briefly MLC (0.8 mg/ml) was phosphorylated for
1 h at room temperature with MLCK (50 µg/ml) in buffer
containing 50 mM Tris-HCl, pH 7.4, 5 mM
magnesium acetate, 0.1 mM CaCl2, 0.1 mg/ml
calmodulin, 0.35 M NaCl, 50 µM
[-32P]ATP, passed through 2× 1-ml spin columns with
Sephadex G-25 (Amersham Pharmacia Biotech, Uppsala, Sweden),
equilibrated with assay buffer, and dialyzed for 18 h at 4 °C
with 2 × 5 liters of assay buffer. Phosphatase activities were
then quantified by measuring release of radioactivity from
[-32P]MLC in the presence of HUVEC lysates as
described (5).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (126K):
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Fig. 1.
Mox-LDL induces a reorganization of the actin
cytoskeleton in a Rho/Rho kinase-dependent manner.
HUVEC were not stimulated (a), exposed to mox-LDL (2 min,
250 µg/ml) (b), treated with C3 transferase (24 h, 5 µg/ml) (c), pretreated with C3 transferase and then
exposed to mox-LDL (d), treated with Y-27632 (30 min, 10 µM) (e), pretreated with Y-27632 and exposed
to mox-LDL (f), or exposed to native LDL (2 min, 250 µg/ml) (g). Cells were fixed and stained for actin using
rhodamine-phalloidin.
View larger version (25K):
[in a new window]
Fig. 2.
Mox-LDL increases transendothelial diffusion
of HRP in a Rho/Rho kinase-dependent manner. HUVEC
were incubated without or with 5 µg/ml C3 transferase (C3)
from C. botulinum for 24 h or for 30 min with 10 µM Rho kinase inhibitor Y-27632 and exposed to mox-LDL or
native LDL (2 min, 250 µg/ml). Transendothelial diffusion of HRP was
determined spectrophotometrically as described under "Experimental
Procedures." Each bar represents the mean ± S.E. of
5-8 measurements.
View larger version (11K):
[in a new window]
Fig. 3.
Mox-LDL stimulates MLC phosphorylation and
inhibits MLC phosphatase activity. a, MLC phosphatase
activity was measured in HUVEC stimulated with mox-LDL (250 µg/ml)
for different time periods. Phosphatase inactivation was maximal
between 30 s and 2 min of stimulation. Results are mean ± S.E. of three experiments. b, HUVEC were stimulated with
mox-LDL (250 µg/ml) for different time periods. MLC phosphorylation
was determined by Western blot using a specific antibody to
phosphorylated MLC. MLC phosphorylation was maximal after 2 min of
stimulation. Results are the mean ± S.E. of seven experiments.
The asterisk (*) indicates MLC phosphorylation after
stimulation of endothelial cells with native LDL (2 min, 250 µg/ml).
View larger version (12K):
[in a new window]
Fig. 4.
Mox-LDL-induced MLC phosphorylation is
mediated by Rho/Rho kinase. HUVEC were stimulated with mox-LDL
(250 µg/ml) as indicated. MLC phosphorylation was then determined by
Western blot using an antibody to phosphorylated MLC. The lower
molecular weight band is because of an unspecific cross-reaction with
the secondary antibody. In cells treated with C3 transferase (24 h, 5 µg/ml) or with Y-27632 (Y) (30 min, 10 µM),
mox-LDL-induced (2 min, 250 µg/ml) MLC phosphorylation was completely
blocked. A Western blot representative of three similar experiments is
shown.
View larger version (110K):
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Fig. 5.
. Mox-LDL induces incorporation of
phospho-MLC into stress fibers. Human endothelial cells were not
stimulated (a), stimulated with mox-LDL (2 min, 250 µg/ml)
(b), treated with C3 transferase (24 h, 5 µg/ml) and then
stimulated with mox-LDL (c), pretreated with Y-27632 (30 min, 10 µM) and then stimulated with mox-LDL
(d), or treated with n-LDL (2 min, 250 µg/ml)
(e). Cells were then fixed and stained for phosphorylated
MLC.
View larger version (20K):
[in a new window]
Fig. 6.
Mox-LDL does not increase cytosolic
Ca2+ concentration. HUVEC were loaded with
Fura 2-AM and stimulated with mox-LDL (150 µg/ml). Cytosolic
Ca2+ concentration was then traced in 38 single cells.
mox-LDL yielded no increased intracellular Ca2+-levels,
whereas cells responded well to thrombin (1 unit/ml).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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ACKNOWLEDGEMENTS |
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We thank Carola Meister and Barbara Böhlig for expert technical assistance and Prof. P. C. Weber, Institut für Prophylaxe der Kreislaufkrankheiten for support. Smooth muscle MLC and MLCK were a generous gift from Kozo Kaibuchi, Nara Institute of Science and Technology, Ikoma, Japan. Anti-phospho-MLC antibody was kindly provided by Dr. J. M. Staddon, Eisai Co., London, UK.
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FOOTNOTES |
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* This study was supported by Ernst und Berta Grimmke-Stiftung, Deutsche Forschungsgemeinschaft (GRK 438), August Lenz-Stiftung, Wilhelm Sander-Stiftung and NWO grant 90268241.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ These authors contributed equally to this work.
¶ To whom correspondence should be addressed. Tel.: +49/89/ 5160-4376; Fax: +49/89/5160-4382; E-mail: messler@klp.med.uni- muenchen.de.
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ABBREVIATIONS |
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The abbreviations used are: mox-LDL, mildly oxidized low density lipoprotein; HRP, horseradish peroxidase; HUVEC, human umbilical vein endothelial cell; LPA, lysophosphatidic acid; MLC, myosin light chain; MLCK, myosin light chain kinase; PBS, phosphate-buffered saline.
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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  E. Behling-Kelly, D. McClenahan, K. S. Kim, and C. J. Czuprynski Viable "Haemophilus somnus" Induces Myosin Light-Chain Kinase-Dependent Decrease in Brain Endothelial Cell Monolayer Resistance Infect. Immun., September 1, 2007; 75(9): 4572 - 4581. [Abstract] [Full Text] [PDF]
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 A. W. Orr, R. Stockton, M. B. Simmers, J. M. Sanders, I. J. Sarembock, B. R. Blackman, and M. A. Schwartz Matrix-specific p21-activated kinase activation regulates vascular permeability in atherogenesis J. Cell Biol., February 26, 2007; 176(5): 719 - 727. [Abstract] [Full Text] [PDF]
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 A. Nohria, M. E. Grunert, Y. Rikitake, K. Noma, A. Prsic, P. Ganz, J. K. Liao, and M. A. Creager Rho Kinase Inhibition Improves Endothelial Function in Human Subjects With Coronary Artery Disease Circ. Res., December 8, 2006; 99(12): 1426 - 1432. [Abstract] [Full Text] [PDF]
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 N. Duerrschmidt, O. Zabirnyk, M. Nowicki, A. Ricken, F. A. Hmeidan, V. Blumenauer, J. Borlak, and K. Spanel-Borowski Lectin-Like Oxidized Low-Density Lipoprotein Receptor-1-Mediated Autophagy in Human Granulosa Cells as an Alternative of Programmed Cell Death Endocrinology, August 1, 2006; 147(8): 3851 - 3860. [Abstract] [Full Text] [PDF]
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 D. Mehta and A. B. Malik Signaling Mechanisms Regulating Endothelial Permeability Physiol Rev, January 1, 2006; 86(1): 279 - 367. [Abstract] [Full Text] [PDF]
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 J. P. Alberding, A. L. Baldwin, J. K. Barton, and E. Wiley Effects of pulsation frequency and endothelial integrity on enhanced arterial transmural filtration produced by pulsatile pressure Am J Physiol Heart Circ Physiol, August 1, 2005; 289(2): H931 - H937. [Abstract] [Full Text] [PDF]
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 I. A. Kolosova, S.-F. Ma, D. M. Adyshev, P. Wang, M. Ohba, V. Natarajan, J. G. N. Garcia, and A. D. Verin Role of CPI-17 in the regulation of endothelial cytoskeleton Am J Physiol Lung Cell Mol Physiol, November 1, 2004; 287(5): L970 - L980. [Abstract] [Full Text] [PDF]
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 W. Feneberg, M. Aepfelbacher, and E. Sackmann Microviscoelasticity of the Apical Cell Surface of Human Umbilical Vein Endothelial Cells (HUVEC) within Confluent Monolayers Biophys. J., August 1, 2004; 87(2): 1338 - 1350. [Abstract] [Full Text] [PDF]
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 M. Pellegrino, E. Furmaniak-Kazmierczak, J. C. LeBlanc, T. Cho, K. Cao, S. M. Marcovina, M. B. Boffa, G. P. Cote, and M. L. Koschinsky The Apolipoprotein(a) Component of Lipoprotein(a) Stimulates Actin Stress Fiber Formation and Loss of Cell-Cell Contact in Cultured Endothelial Cells J. Biol. Chem., February 20, 2004; 279(8): 6526 - 6533. [Abstract] [Full Text] [PDF]
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Z. Mallat, A. Gojova, V. Sauzeau, V. Brun, J.-S. Silvestre, B. Esposito, R. Merval, H. Groux, G. Loirand, and A. Tedgui Rho-Associated Protein Kinase Contributes to Early Atherosclerotic Lesion Formation in Mice Circ. Res., October 31, 2003; 93(9): 884 - 888. [Abstract] [Full Text] [PDF]
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A. P. SOMLYO and A. V. SOMLYO Ca2+ Sensitivity of Smooth Muscle and Nonmuscle Myosin II: Modulated by G Proteins, Kinases, and Myosin Phosphatase Physiol Rev, October 1, 2003; 83(4): 1325 - 1358. [Abstract] [Full Text] [PDF]
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 Z. Wang, M. C. Lanner, N. Jin, D. Swartz, L. Li, and R. A. Rhoades Hypoxia Inhibits Myosin Phosphatase in Pulmonary Arterial Smooth Muscle Cells: Role of Rho-Kinase Am. J. Respir. Cell Mol. Biol., October 1, 2003; 29(4): 465 - 471. [Abstract] [Full Text] [PDF]
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 J. Galle, A. Mameghani, S.-S. Bolz, S. Gambaryan, M. Gorg, T. Quaschning, U. Raff, H. Barth, S. Seibold, C. Wanner, et al. Oxidized LDL and its Compound Lysophosphatidylcholine Potentiate AngII-Induced Vasoconstriction by Stimulation of RhoA J. Am. Soc. Nephrol., June 1, 2003; 14(6): 1471 - 1479. [Abstract] [Full Text] [PDF]
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T. Seko, M. Ito, Y. Kureishi, R. Okamoto, N. Moriki, K. Onishi, N. Isaka, D. J. Hartshorne, and T. Nakano Activation of RhoA and Inhibition of Myosin Phosphatase as Important Components in Hypertension in Vascular Smooth Muscle Circ. Res., March 7, 2003; 92(4): 411 - 418. [Abstract] [Full Text] [PDF]
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 C. Rodriguez, B. Raposo, J. Martinez-Gonzalez, L. Casani, and L. Badimon Low Density Lipoproteins Downregulate Lysyl Oxidase in Vascular Endothelial Cells and the Arterial Wall Arterioscler. Thromb. Vasc. Biol., September 1, 2002; 22(9): 1409 - 1414. [Abstract] [Full Text] [PDF]
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 M. S. Segal, A. Bihorac, and M. Koc Circulating endothelial cells: tea leaves for renal disease Am J Physiol Renal Physiol, July 1, 2002; 283(1): F11 - F19. [Abstract] [Full Text] [PDF]
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G. P. van Nieuw Amerongen and V. W.M. van Hinsbergh Cytoskeletal Effects of Rho-Like Small Guanine Nucleotide-Binding Proteins in the Vascular System Arterioscler. Thromb. Vasc. Biol., March 1, 2001; 21(3): 300 - 311. [Abstract] [Full Text] [PDF]
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 B Wojciak-Stothard, S Potempa, T Eichholtz, and A. Ridley 9Rgr; and Rac but not Cdc42 regulate endothelial cell permeability J. Cell Sci., January 4, 2001; 114(7): 1343 - 1355. [Abstract] [PDF]
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 K. Bauer, M. Kratzer, M. Otte, K. L. de Quintana, J. Hagmann, G. J. Arnold, C. Eckerskorn, F. Lottspeich, and W. Siess Human CLP36, a PDZ-domain and LIM-domain protein, binds to alpha -actinin-1 and associates with actin filaments and stress fibers in activated platelets and endothelial cells Blood, December 15, 2000; 96(13): 4236 - 4245. [Abstract] [Full Text] [PDF]
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 S.-S. Bolz, J. Galle, R. Derwand, C. de Wit, and U. Pohl Oxidized LDL Increases the Sensitivity of the Contractile Apparatus in Isolated Resistance Arteries for Ca2+ via a Rho- and Rho Kinase-Dependent Mechanism Circulation, November 7, 2000; 102(19): 2402 - 2410. [Abstract] [Full Text] [PDF]
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G. P. v. N. Amerongen, S. v. Delft, M. A. Vermeer, J. G. Collard, and V. W. M. van Hinsbergh Activation of RhoA by Thrombin in Endothelial Hyperpermeability : Role of Rho Kinase and Protein Tyrosine Kinases Circ. Res., August 18, 2000; 87(4): 335 - 340. [Abstract] [Full Text]
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 M. ESSLER, M. RETZER, M. BAUER, K. J. ZANGL, G. TIGYI, and W. SIESS Stimulation of Platelets and Endothelial Cells by Mildly Oxidized LDL Proceeds through Activation of Lysophosphatidic Acid Receptors and the Rho/Rho-Kinase Pathway: Inhibition by Lovastatin Ann. N.Y. Acad. Sci., April 1, 2000; 905(1): 282 - 286. [Full Text] [PDF]
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