Introduction
Atrial fibrillation (AF) is the most common
arrhythmia observed in humans and accounts for significant
morbidity and mortality rates. It is a mechanistically complex
arrhythmia for which available therapies remain suboptimal
(1). Atrial fibrosis is a common
characteristic of clinical AF and is associated with AF in a
variety of experimental paradigms (2). Increased collagen deposition has
been documented in patients with lone AF compared with the control
subjects with normal sinus rhythm (3). It therefore stands to reason that
future therapies for AF should be aimed at reversing or delaying
the fibrotic process (4).
Atrial fibroblasts are a quantitatively and
qualitatively important cell type of the heart. Extensive evidence
indicates that atrial fibrosis, involving fibroblast
differentiation and increased fibroblast-derived ECM protein
expression, plays an important role in AF (5). Animal studies have demonstrated the
importance of transforming growth factor-β1 (TGF-β1) in atrial
fibrosis. The inhibition of TGF-β1 prevents atrial fibrosis, atrial
conduction abnormalities and vulnerability to AF (6). TGF-β1 is fibrogenic cytokine that
plays a key role in the differentiation of fibroblasts into
myofibroblasts, which express α-smooth muscle actin (α-SMA) and
produce more collagen than fibroblasts (7). The primary TGF-β1 signal
transduction pathway is the conserved Smad pathway (8). Receptor-regulated Smads (R-Smads,
including Smad2 and Smad3) and inhibitory-Smad7 (I-Smad7) have been
well characterized as key downstream effectors of TGF-β1 signaling
(9). The TGF-β/Smad pathway is
recognized as a traditional signaling pathway that initiates the
activation of cardiac fibroblasts (10,11). In addition, previous studies have
shown that TGF-β/Smad signaling is tightly controlled by
mitogen-activated protein (MAP) kinase signaling cascades,
particularly extracellular signal-regulated kinase 1/2 (ERK1/2)
(12,13).
Sodium tanshinone IIA sulfonate (STS) is a
derivative of tanshinone IIA, which is a lipid-soluble
pharmacologically active component isolated from the rhizome of the
Chinese herb, Salvia miltiorrhiza, a well-known traditional
Chinese medicine. Tanshinone IIA has been shown to possess a
variety of biological activities in the cardiovascular system, such
as antioxidant, anticoagulant, anti-atherosclerotic, anti-apoptotic
and antihypertrophic activities (14–17). Tanshinone IIA has also been shown
to possess anti-fibrotic activities (18,19). In the present study, we explored
the effects and mechanisms of action of STS on the TGF-β1-induced
collagen expression and differentiation of atrial fibroblasts into
myofibroblasts in vitro, demonstrating the potential
application of STS in clinical practice for the treatment of atrial
fibrosis and AF.
Materials and methods
Materials
Week-old neonatal Wistar rats were obtained from the
Experimental Animal Center of Tongji Medical College, Grate II. The
present study complied with the National Institutes of Health
Guidelines on the Use of Laboratory Animals and was approved by the
Animal Research Committee of Tongji Medical College, Huazhong
University of Science and Technology (Wuhan, China). STS (99.5%)
was obtained from the Research Center of Traditional Chinese
Medicine (Wuhan, China) and was dissolved in phosphate-buffered
saline (PBS). TGF-β1 was obtained from Sigma-Aldrich (St. Louis,
MO, USA). PD98059 (ERK inhibitor) was purchased from Calbiochem
(San Diego, CA, USA). Antibodies, such as those for collagen type I
(no. sc-8784)/III (no. sc-8781), α-SMA (no. sc-32251),
phosphorylated (p)Smad2 (no. sc-101801) and pERK1/2 (no.
sc-101761), were purchased from Santa Cruz Biotechnology, Inc.
(Dallas, TX, USA). All other chemicals used were of the highest
quality available commercially. The molecular structure of STS is
illustrated in Fig. 1.
Cell culture
Primary cultured atrial fibroblasts were prepared as
previously described (20).
Briefly, the atria from week-old neonatal Wistar rats were
separated and minced with scissors into 2–3-mm3
fragments in ice-cold balanced salt solution. The fragments were
then digested by 4–6 cycles (15 min each) of incubation with 0.125%
trypsin. At the end of each cycle, the supernatant was stored on
ice after the addition of fetal bovine serum (FBS) to neutralize
trypsin. The dissociated cells were collected by centrifugation at
1,000 × g for 10 min, followed by resuspension in Dulbecco’s
modified Eagle’s medium (DMEM) supplemented with 10% FBS.
Thereafter, the cells were incubated in a humidified atmosphere of
5% CO2 at 37°C. After 1 h of incubation, the atrial
fibroblasts attached to the dishes, whereas cardiomyocytes
remaining in the medium were discarded. The attached atrial
fibroblasts were further cultured to confluence and then passaged
at a 1:3 dilution. The first and second passages fibroblasts were
used for all the experiments.
Collagen production assay
The collagen content in the fibroblast cultures was
measured by hydroxyproline assay as previously described (21). Briefly, the fibroblasts were made
quiescent by culture in serum-free DMEM for 24 h. The quiescent
cells were then pre-treated with STS (3, 10 and 30 μM) for
30 min and then exposed to TGF-β1 (5 ng/ml) for 48 h. The protein
content in the cell lysates the was measured using Coomassie
reagent (Santa Cruz Biotechnology, Inc.).
Collagen synthesis assay
Collagen synthesis was evaluated by measuring
[3H]proline incorporation as previously described
(22). In brief, the fibroblasts
were made quiescent by culture in serum-free DMEM for 24 h.
Subsequently, these cells were treated with STS (3, 10 and 30
μM) for 30 min prior to stimulation with 5 ng/ml TGF-β1 for
24 h. Collagen synthesis was assessed by the addition of 1
μCi/mL [3H] proline (Amersham Biosciences,
Piscataway, NJ, USA) for 6 h. The cells were washed with PBS and
ice-cold 10% trichloroacetic acid. The cells were then solubilized
and the cell extracts were analyzed in a liquid scintillation
counter [1450; PerkinElmer Enspire (China) Co., Ltd., Shanghai,
China].
Immunocytochemistry/α-SMA staining
Following TGF-β1 (5 ng/ml) stimulation for 24 h with
or without the presence of STS (10 μM), the cells were
washed with PBS, fixed with 4% paraformaldehyde in PBS for 20 min,
and then permeablized with 0.1% Triton X-100/PBS for 20 min. After
the cells were incubated with a blocker (3% bovine serum) for 30
min, the specific anti-α-SMA antibody was added. The cells were
visualized under a fluorescence microscope (Olympus, Tokyo,
Japan).
Nuclear, cytoplasmic and total protein
extract preparation and western blot analysis
Nuclear and cytoplasmic extracts of fibroblasts were
prepared as previously described (23). Nuclear proteins and cytoplasmic
proteins were extracted using a nuclear extraction kit (Panomics,
Santa Clara, CA, USA) following the manufacturer’s instructions and
stored at −20°C until used in western blot analysis. Proteins (30
μg) were separated on 4–15% gradient polyacrylamide gels,
transferred onto PVDF membranes and probed with the following
antibodies: mouse monoclonal anti-α-SMA (no. A2547), rabbit
anti-Smad2 (no. SAB4501806), rabbit anti-phospho Smad2 (pSmad2; no.
sc-101801), rabbit anti-Smad3 (no. SAB4200342), rabbit anti-phospho
Smad3 (pSmad3; no. SAB4504210), rabbit anti-Smad7 (no. SAB4200345),
rabbit anti-phospho-ERK1/2 (no. sc-101761), and rabbit
anti-total-ERK1/2 (no. sc-292838). All blots were exposed for
optimal lengths of time for visualization.
Statistical analysis
The results are expressed as the means ± SD.
Statistical significance was determined by one-way ANOVA. The
differences were considered statistically significant at a value of
P<0.05.
Results
Effects of STS on the TGF-β1-induced
collagen production and synthesis
TGF-β1 (5 ng/ml) significantly enhanced collagen
production, which was attenuated by treatment with STS (3, 10 and
30 μM) (Fig. 2).
Consistent with the increase in collagen production, TGF-β1 induced
a significant increase in the rate of [3H]proline
incorporation, which was also markedly suppressed by treatment with
STS. However, STS alone had no effect on collagen production and
synthesis.
Effects of STS on the TGF-β1-induced
expression of collagen type I and III
Type I and III collagen constitute two-thirds of
cardiac collagen. TGF-β1 significantly enhanced the expression of
collagen type I and III; this effect was attenuated by treatment
with STS (3, 10 and 30 μM) (Fig. 3). Consistent with the increase in
collagen expression, TGF-β1 (5 ng/ml) induced a significant
increase in the rate of [3H]proline incorporation, which
was also significantly suppresswed by treatment with STS.
Therefore, STS attenuates TGF-β1-induced fibrotic responses in
atrial fibroblasts.
Effects of STS on the TGF-β1-induced
expression of α-SMA
The expression of α-SMA is a hallmark of
myofibroblast differentiation (24–26). Therefore, we assessed the
expression levels of α-SMA 24 h following treatment with TGF-β1 in
the presence or absence of STS. TGF-β1 stimulation increased the
intensity and organization of α-SMA, which was markedly suppressed
by treatment with 10 μM STS (Fig. 4). Moveover, western blot analysis
revealed that treatment with 5 ng/ml TGF-β1 significantly enhanced
the expression of α-SMA, which was suppressed by STS.
Effects of STS on the TGF-β1-induced
phosphorylation of Smad2, Smad3 and ERK1/2, and Smad7
TGF-β1 signals were followed by the activation of
cytoplasmic effectors, such as Smad proteins. The phosphorylation
of Smad2/Smad3 and the subsequent translocation of Smad2/Smad3 to
the nucleus are critical steps in cell signaling through this
pathway. Inhibitory Smads, such as Smad7, antagonize these
processes (12,13,27). Western blot analysis revealed that
TGF-β1 significantly increased the phosphorylation of Smad2 and
Smad3. STS significantly blocked the TGF-β1-induced expression of
pSmad2 and pSmad3 (Fig. 5).
However, STS did not exert any significant effect on Smad7
expression (Fig. 5).
In addition, a recent study revealed that the
pharmacological inhibition of ERKs blocked the gene expression of
TGF-β1-stimulated collagen in cardiac fibroblasts (28). We also found that treatment with
PD98059 (an ERK inhibitor) at 25 μM decreased the
TGF-β1-induced expression of α-SMA (Fig. 6). Another study demonstrated that
the activation of ERK was necessary for both myofibroblast
differentiation and ECM synthesis induced by TGF-β1 in the cardiac
fibroblasts of neonatal rats (29). Therefore, we examined whether
ERK1/2 activation is induced by stimulation with TGF-β1 in atrial
fibroblasts and whether STS has any effect on this process. The
phosphorylation of ERK1/2 was increased in the TGF-β1-stimulated
fibroblasts and was significantly suppressed by treatment with STS
(Fig. 6).
Effects of STS on the TGF-β1-induced
nuclear translocation of pSmad2 and pSmad3
To determine whether the inhibition of
TGF-β1-induced expression of α-SMA by STS is dependent on events
downstream of the phosphorylation of Smad2 and Smad3, we examined
the effects of STS on the TGF-β1-induced nuclear translocation of
pSmad2 and pSmad3 in atrial fibroblasts. Protein samples were
prepared from cytoplasmic and nuclear fractions form the different
treatment groups. Treatment with TGF-β1 resulted in a strong
accumulation of pSmad2 and pSmad3 in the nucleus (Fig. 7). The above effects were
significantly suppressed by treatment with STS.
Discussion
AF results in undirected wavefronts in the atria
(30). This leads to functionally
inadequate atrial contractions, which slow the blood flow velocity
in the atria, thus increasing atrial blood load and preventing
optimal ventricular filling (31). Atrial fibrosis is a common
pathological condition observed in AF, particularly in
long-standing AF. Atrial fibrosis is also observed in AF associated
with underlying structural disease, including various forms of
cardiomyopathies and mitral valve diseases (32,33).
Atrial fibroblasts are the major source of collagen
in the atrial endocardium and behave differently than ventricular
fibroblasts over a range of in vitro and in vivo
paradigms. Atrial fibroblasts show enhanced reactivity, which may
explain greater atrial fibrotic responses (5,34).
As they have the form of thick fiber with a high tensile strength,
collagen type I and III contents are considered major determinants
of myocardial stiffness (35–37). TGF-β1 is a key fibrogenic cytokine
both in vitro and in vivo (38). As previously demonstrated, in
TGF-β1-deficient mice and rats treated with anti-TGF-β1 antibodies,
cardiac fibrosis is blunted (39). Many other fibrogenic factors, such
as angiotensin II, and mechanical stretch and oxidative stress
increase TGF-β1 secretion in fibroblasts (40). The number of myofibroblasts has
been shown to be increased in rats with cardiac fibrosis resulting
from hypertension or myocardial infarction (41). Activated myofibroblasts are
considered the major source of ECM components, such as collagen
type I and III (42). Hence, the
conversion of fibroblasts into myofibroblasts by TGF-β1 is an
important mechanism in the development of cardiac fibrosis
(43).
Tanshinone IIA is most abundant and structurally
representative of the tanshinones of Salvia miltiorrhiza
(44). STS has also shown to be a
promising drug that reduces cardiac remodeling by suppressing
cardiomyocyte hypertrophy (45).
Moreover, STS has been shown to possess antifibrotic activities
in vivo (18,19). Tanshinone IIA has also been
reported to have an antiarrhythmic effect, decreasing the duration
of lethal arrhythmias and reducing the incidence of ventricular
tachycardia and/or ventricular fibrillation (VT/VF) in rats with
myocardial infarction (46).
Nevertheless, to date, little is known of the cellular and
molecular mechanisms responsible for the STS-mediated antifibrotic
effects in atrial fibroblasts following stimulation with TGF-β1. In
the present study, we attempted to explore the effects and
mechanisms of action of STS on the TGF-β1-induced differentiation
of cultured atrial fibroblasts into myofibroblasts.
In the present in vitro study, we
demonstrated that TGF-β1 increased collagen production and
synthesis. Furthermore, TGF-β1 increased the expression of collagen
type I and III in atrial fibroblasts. These results were consistent
with those of a recent study (47). The above effects were
significantly suppressed by treatment with STS. Therefore, STS
supresses the TGF-β1-induced expression of collagen type I and III
through the attenuation of collagen synthesis. To further determine
the effects of STS on the TGF-β1-induced differentiation of atrial
fibroblasts into myofibroblasts, immunofluorescence staining for
α-SMA was used to detect α-SMA expression and the morphological
changes of atrial fibroblasts. Compared with the control group, the
atrial fibroblasts stimulated with 5 ng/ml of TGF-β1 showed bright
staining for α-SMA, the appearance of stress fibers and a larger
cell size. These effects be were suppressed by treatment with STS
(Fig. 4), which indicates that
STS has obvious antifibrotic effects.
The biological effects of TGF-β1 are mediated
through a complex of type II and I receptors characterized as
serine-threonine kinases that transduce intracellular signals
through both Smad and non-Smad pathways. The activated receptor
complex phosphorylates R-Smads, such as Smad2 and Smad3, which form
homomeric and heteromeric complexes with a co-Smad (Smad4). These
active Smad complexes enter the nucleus, where they bind to target
genes and directly regulate their transcription (9,48).
Thus, the phosphorylation of R-Smads followed by translocation to
the nucleus is a critical step in the activation of TGF-β1
signaling. Indeed, as previously demonstrated, the transfection of
atrial fibroblasts with a silencing RNA against Smad2 blocked not
only the phosphorylation of Smad2, but also the differentiation of
fibroblasts into myofibroblasts in response to TGF-β1 (49). As expected, our results revealed
that pSmad2 and pSmad3 expression was significantly increased in
the TGF-β1-treated cells compared with the controls, and that this
effect was significantly inhibited by treatment with STS. Moreover,
STS suppressed the TGF-β1-induced nuclear translocation of pSmad2
and pSmad3 (Fig. 7). Smad7 acts
as a negative regulator for both TGF-β/Smad signaling pathways
(50). These results suggest that
STS suppresses the differentiation of atrial fibroblasts into
myofibroblasts and collagen synthesis in part through the
inhibition of Smad2 and Smad3 phosphorylation.
TGF-β1/Smad signaling is tightly controlled by the
MAP kinase signaling cascades, particularly ERK1/2, in many cell
types (51,52). Thus, whereas the ERK1/2 cascade
may directly regulate collagen gene transcription, it may also
enhance Smad-dependent signaling in atrial fibroblasts in such a
manner that the inhibition of ERK signaling also attenuates Smad
signaling. Certain studies have reported a positive correlation
between TGF-β1 and the ERK signaling pathway (53,54). In the present study, we determined
the importance of ERK1/2 in TGF-β1-induced atrial fibrosis. TGF-β1
increased the expression of α-SMA, and this effect was decreased by
treatment with PD98059 (an ERK inhibitor, 25 μM) (Fig. 6). Moreover, TGF-β1 enhanced the
ERK1/2 phosphorylation of ERK1/2, which was depressed by STS.
Therefore, the inhibition of ERK1/2 phosphorylation may be one of
the mechanisms involved in the downregulation of the TGF-β1/Smad
pathway by STS.
In conclusion, the present study provides important
new insight into the molecular mechanisms of action of STS in
atrial fibroblasts. Our data also demonstrate that STS exerts
antifibrotic effects by modulating the differentiation of atrial
fibroblasts through ERK1/2 phosphorylation and the Smad2/3 pathway.
Although the precise mechanisms through which STS attenuates the
development of atrial fibrosis remain to be further clarified, the
understanding of the pharmacological effects of STS on atrial
fibroblasts may contribute to the use of STS in the treatment of
patients suffering from cardiovascular diseases.
Acknowledgments
This study was supported by a grant (81102691) from
the National Natural Science Foundation of China. The authors wish
to express their thanks to Dr Zhao for his generous technical
support.
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