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J Biol Chem, Vol. 274, Issue 43, 30611-30616, October 22, 1999
From the The transcription factor activator protein-1
(AP-1) reportedly plays an important role in the induction of
neoplastic transformation and multiple genes involved in cell
proliferation, differentiation, and inflammation. To investigate the
mechanisms of silica-induced carcinogenesis, AP-1-luciferase reporter
transgenic mice were used as an in vivo model, whereas the
JB6 mouse epidermal cell line and a rat lung epithelial cell line were
employed as in vitro models to study the effects of silica
at the molecular level. Freshly fractured silica caused an 8-fold
increase in AP-1 activity in JB6 cells and a 2.5-fold increase in rat
lung epithelial cells. The induction of AP-1 activity in cultured cell
lines was time- and dose-dependent. Intratracheal
administration of silica was also able to induce AP-1 transactivation
in transgenic mice. AP-1 activation was first observed at 2 days after
silica administration and reached its maximum at 3 days post-exposure
of the mice to silica. The signal transduction pathways for AP-1
activation were also investigated using these cell lines. The results
demonstrate that freshly fractured silica stimulates mitogen-activated
protein kinase (MAPK) family members, as determined by the
phosphorylation of p38 MAPK and extracellular signal-regulated protein
kinases (ERKs). Inhibition of ERKs with PD98059 or of p38 with SB203580 significantly inhibited silica-induced AP-1 activation. These findings
demonstrate for the first time that freshly fractured silica induces
AP-1 activation, which may be mediated through p38 MAPK and ERK
pathways. Unraveling the complex mechanisms associated with these
events may provide insights into the initiation and progression of
silica-induced carcinogenesis.
Epidemiologic and pathologic studies have established that
occupational exposure to crystalline silica is associated with the
development of acute and chronic pulmonary silicosis (1, 2). Acute
silicosis usually occurs in individuals who work in occupations where
silica is fractured or ground into fine powder by mechanical processes.
Acute silicosis becomes clinically apparent within 2-5 years after
exposure and frequently results in death due to hypoxia (3). Chronic
silicosis occurs in workers with prolonged exposure to
silica-containing dusts, with clinically apparent disease developing
after 20 or more years of exposure (3). In addition, increasing
evidence obtained from epidemiologic and laboratory animal studies in
recent years suggests that crystalline silica may be a carcinogen (4,
5). For example, inhalation of silica has been shown to be carcinogenic
in rats, whereas intratracheal instillation has been shown to be
carcinogenic in other animals (6-9). Intrapleural administration of
crystalline silica in rats leads to the induction of localized
malignant histiocytic lymphomas. Epidemiologic studies also show that
there is an increased lung cancer risk in many, but not all, human
subjects with silicosis (4, 5). Based on current evidence obtained from
studies on laboratory animals and epidemiologic studies on humans, the International Agency for Research on Cancer has classified crystalline silica as a human class 1 carcinogen (5).
Although silica is now a documented carcinogen, the molecular
mechanisms involved in silica-induced carcinogenesis remain poorly
understood. Previous studies have shown that silica causes direct DNA
damage and mammalian cell transformation, including binding with
deoxyribonucleic acid, which has been used as an in vitro
analog of cancer induction (10, 11). Earlier studies have demonstrated
that freshly fractured silica is capable of generating hydroxyl
radicals (·OH) upon reaction with aqueous media (12-14).
Superoxide anion radicals (O AP-11 is a transcription
factor that interacts with regulatory DNA sequences known as TPA
response elements or AP-1 sites (20). Many stimuli, including the tumor
promoter TPA and reactive oxygen species, regulate AP-1 binding to the
DNA of the promoter region of a number of intermediate genes that
govern inflammation, proliferation, and apoptosis (21-23). AP-1 and
its regulated gene expression have been reported to play important
roles in neoplastic transformation, tumor progression, and metastasis
(24-27). On the basis of the importance of AP-1 activity in tumor
promotion and progression, we hypothesized that the carcinogenic effect
of silica may be mediated through the activation of AP-1 activity. To
test this hypothesis, we used JB6 P+ mouse epidermal cells
and rat lung epithelial cells as in vitro models and
AP-1-luciferase transgenic mice as an in vivo model for
these studies. The JB6 family of mouse epidermal clonal genetic variants that are P+ or P Reagents and Plasmids--
Eagle's MEM was obtained from
Whittaker Biosciences (Walkersville, MD). Fetal bovine serum,
gentamicin, and L-glutamine were purchased from Life
Technologies, Inc. Luciferase assay substrate was obtained from Promega
(Madison, WI). PhosphoPlus MAPK Antibody kits were purchased from New
England Biolabs Inc. (Beverly, MA). The rat lung epithelial cell line
was obtained from American Type Culture Collection (Manassas, VA). The
AP-1-luciferase reporter plasmid (collagenase-luciferase) and the
CMV-neo vector plasmid were constructed as reported previously (30,
31). PD98059 and SB203580, which are specific MEK1 and p38 kinase
inhibitors (32, 33), respectively, were from Calbiochem.
Preparation of Freshly Fractured Silica--
Crystalline silica
was obtained from the Pennsylvania State University Genetic Center
(State College, PA). The detailed method for preparation of the freshly
fractured silica has been described elsewhere (13). Briefly,
crystalline silica (0.2-10 mm in diameter) was ground for 30 min using
a ball grinder equipped with agate balls. The ground silica was sieved
through a 10-µm mesh filter for 20 min before use. Purity was checked
using x-ray analysis and morphometric analysis, which indicated that
the ground silica had a mean diameter of 3.7 µm.
Generation of Stable Transfectants--
RLE cells were
transfected with the AP-1-luciferase reporter plasmid and the
G418-selecting plasmid pcDNA3-CMV-neo. Fifteen individual clones were
selected by ring isolation and cultured in F12K medium containing 10%
FBS and G418 (200 µg/ml) for 30 days. Stable transfectants were
screened by assaying for luciferase activity following stimulation with
TPA or vanadate. A stable transfectant (RLE/AP02) was established and
cultured in G418-free medium for the experiments.
Cell Culture--
The JB6 P+ mouse epidermal cell
line, which was stably transfected with the AP-1-luciferase reporter
plasmid (JB6/AP/ Assay of AP-1 Activity in Vitro--
A confluent monolayer of
JB6/AP/ Animals and Administration of Silica--
AP-1-luciferase
reporter (2× TPA response element-binding sites) transgenic mice were
originally established by Rincon and Flavell (35). A C57BL/6 male mouse
carrying the 2× TPA response element-luciferase transgene was crossed
with a DBA2 female (SASCO, Omaha, NE) (36). The offspring were screened
for the presence of the AP-1-luciferase reporter gene by testing the
TPA-induced level of luciferase activity. Males and females were housed
separately in solid-bottom polycarbonate cages on ventilated animal
racks (four to five mice per cage) under temperature-, humidity-, and yellow light-controlled conditions. Food and water were available ad libitum.
The AP-1-luciferase reporter-bearing male and female mice (8-12 weeks
old) were randomly divided into six groups consisting of eight mice in
each group. Freshly fractured silica was suspended in 0.9% sterile
NaCl (70 mg/ml) and was administered at 0.07 ml/mouse (5 mg) with an
intratracheal cannula after the animals were anesthetized with sodium
pentobarbital (50 mg/kg). Control mice were instilled intratracheally
with 0.07 ml of 0.9% sterile NaCl/mouse.
Assay of AP-1 Activity in Vivo--
One to four days after
intratracheal instillation of silica, the mice were sacrificed by
exsanguination under deep pentobarbital anesthesia. Lung tissue was
removed and minced with scissors. Lysis buffer (100 µl/10 mg of
tissue) was added, and the tissues were lysed overnight at 4 °C. The
luciferase activity of the tissue supernatant obtained after lysis was
measured with a luminometer as described previously (36). AP-1 activity
is expressed relative to the level of luciferase activity of controls.
Protein Kinase Phosphorylation Assay--
Immunoblotting for
phosphorylation of ERKs, JNKs, and p38 kinase was carried out as
described by the protocol of New England Biolabs Inc. using
phospho-specific antibodies against phosphorylated sites of ERKs, JNKs,
and p38 kinase, respectively. Non-phospho-specific antibodies against
ERKs, JNKs, and p38 kinase proteins provided in each assay kit were
used to normalize the phosphorylation assay using the same transferred
membrane blot.
Electrophoretic Mobility Shift Assay--
Gel shift assays were
performed to detect AP-1 binding activity after exposure to silica. The
nuclear extracts and the 32P-labeled oligonucleotide were
prepared as described previously (34). Briefly, an oligonucleotide
containing the AP-1 binding site (5'-CGCTTGATGAGTCAGCCGGAA-3') was
synthesized and labeled with [32P]dCTP. Nuclear proteins
(3-5 µg), extracted from cells exposed to silica, were mixed with
the labeled probe and incubated at room temperature for 30 min. The
DNA-protein complexes were resolved on a 5% nondenaturing acrylamide
gel. The gel was dried and visualized by autoradiography.
Statistical Analysis--
The data presented are the means ± S.E. of values compared and analyzed using a one-way analysis of
variance. Statistical significance was determined by two-tailed
Student's t test for paired data and is considered
significant at p Establishment of RLE AP-1 Reporter Cells--
To study the AP-1
induction by silica in pulmonary cells, we established a stable
AP-1-luciferase reporter transfectant from the RLE cell line. The
stable transfectants were generated by ring selection. After
transfecting cells with plasmids and selecting by G418, 15 colonies
were isolated. The AP-1 activation of each clone was screened by
measuring luciferase activity induced by TPA or vanadate. One of the
colonies (REL/AP02), with stable luciferase activity, was maintained
for the experimental studies. The AP-1 activity of RLE/AP02 cells was
elevated 2- and 10-fold after a 24-h exposure of the cells to 20 ng/ml
TPA or 40 µM vanadate, respectively (data not shown). The
control cell line transfected with the vector only did not show any
luciferase activity after a 24-h exposure of cells to TPA or vanadate
(data not shown).
Freshly Fractured Silica Causes AP-1 Activation in JB6 and RLE/AP02
Cells--
To explore the effects of silica on the induction of AP-1
activity, 5 × 104 JB6/AP/
Since crystalline silica causes pulmonary epithelial hyperplasia and
neoplastic lesions, we next asked whether freshly fractured silica
induces AP-1 activation in rat lung epithelial cells. Freshly fractured
silica was incubated for 72 h with 5 × 104
RLE/AP02 cells stably transfected with the AP-1-luciferase reporter plasmid. Freshly fractured silica also caused a
dose-dependent induction of AP-1 activation in RLE/AP02
cells (Fig. 2A). At a silica
concentration of 300 µg/ml ( Transactivation of AP-1 by Freshly Fractured Silica in
AP-1-Luciferase Reporter Transgenic Mice--
To investigate whether
similar mechanisms exist in vivo, we used AP-1-luciferase
reporter transgenic mice for these studies. The transgenic mice were
exposed to freshly fractured silica (5 mg/mouse) by intratracheal
instillation of a silica suspension (70 mg/ml in 0.9% sterile NaCl).
At intervals of 1, 2, 3, and 4 days post-exposure, animals were
anesthetized with sodium pentobarbital and sacrificed by
exsanguination; lungs were removed; and their luciferase activities
were measured as described under "Materials and Methods." Elevated
AP-1 transactivation was not detected at 1 day post-exposure (data not
shown). However, AP-1 activation increased significantly at 2 and 3 days post-exposure and decreased to control levels at 4 days
post-exposure (Fig. 3). At day 3 post-exposure, the induction of AP-1 activation in lung tissue by
freshly fractured silica was 24 times higher than that in the control
group.
Activation of ERKs and p38 Kinase by Freshly Fractured Silica in
JB6 Cells--
Since mitogen-activated protein kinases, including p38
kinase, ERKs, and JNKs, are the upstream kinases responsible for c-Jun phosphorylation and AP-1 activation (37-40), we tested which class of
MAPK is involved in the AP-1 activation by silica. We examined the
influences of silica on the phosphorylation of ERK1, ERK2, JNKs, and
p38 kinases. Using antibodies specific for the above MAPK family and
phospho-specific for the phosphorylated MAPKs, we studied ERK1, ERK2,
JNKs, and p38 kinase proteins and the protein phosphorylation of ERK1,
ERK2, JNKs, and p38 kinase in JB6 P+ cells. Exposure to
freshly fractured silica significantly stimulated the phosphorylation
of p38 kinase and ERKs. The time course of p38 kinase phosphorylation
induced by silica (150 µg/ml) is shown in Fig.
4A. Phosphorylation of p38
kinase was first apparent at 15 min after exposure to silica. and its
maximal activation was obtained at 2 h. To examine the dose
dependence of the p38 kinase response in cells exposed to silica, JB6
cells were treated for 2 h with various concentrations of silica.
A dose-related increase in p38 kinase phosphorylation was observed in
cells treated with increasing concentrations of silica, i.e.
with prominent increases at 100-200 µg/ml (Fig. 4B).
Freshly fractured silica (150 µg/ml) also caused phosphorylation of
ERK1 and ERK2 in a time-dependent manner (Fig.
5). In contrast, silica did not affect
the phosphorylation levels of JNKs (Fig.
6). Similar results were obtained using
the RLE cell line (data not shown). These results suggest that ERKs and
p38 kinase, but not JNKs, may be involved in silica-induced AP-1
activation in JB6 cells as well as in RLE cells.
Inhibition of ERKs or p38 Kinases by Specific Inhibitors Also
Blocks Freshly Fractured Silica-induced AP-1 Activation--
To
further confirm that activation of AP-1 by silica is mediated through
p38- and ERK-dependent signal transduction pathways, we
examined the effects of PD98059 and SB203580 on silica-induced AP-1
activation. PD98059 has been shown to act as a highly selective inhibitor of MEK1 activation, whereas SB203580 has been shown to be a
specific inhibitor of p38 kinase. MEK1 is an upstream activator of
ERKs. Silica-induced AP-1 activation was significantly inhibited by 20 µM PD98059 or 2 µM SB203580 (Fig.
7).
PD98059 and SB203580 Inhibit Freshly Fractured Silica-induced AP-1
DNA Binding Activity--
To study the molecular basis of the
induction of AP-1 activity by silica and to further confirm the above
findings, the AP-1 DNA binding activity was analyzed by gel shift
assay. As shown in Fig. 8, silica induced
AP-1 DNA binding activity, and PD98059 or SB203580 inhibited
silica-induced AP-1 DNA binding activity. These data provide further
support that ERKs and p38 kinase are involved in silica-induced AP-1
activation.
Occupational exposure to silica is associated with the development
of silicosis and lung cancer (1, 4, 5). The molecular mechanisms
involved in silica-induced carcinogenesis are unclear. We hypothesize
that activation of nuclear transcription factors induced by silica is a
primary event in the initiation of signal transduction cascades at the
cell membrane level leading to the induction of early response genes
that are critical in carcinogenesis. In this study, we examined the
effect of silica on the activation of AP-1 and the signal transduction
pathways involved in AP-1 activation in cell culture models and in
transgenic mice. The results show that silica stimulates AP-1 DNA
binding activity as well as AP-1 transactivation activity. Silica
induced an 8-fold increase in AP-1 activity in JB6 cells and a 2.5-fold
increase in RLE cells. Silica also stimulated AP-1 transactivation in
pulmonary tissues of transgenic mice. At 3 days after intratracheal
instillation of silica, AP-1 activity was elevated 23-fold as compared
with the controls. Most important, we found that phosphorylation of ERK1, ERK2, and p38 kinases, which are involved in silica-induced AP-1
activation, was induced by freshly fractured silica. These data
demonstrate for the first time that freshly fractured silica induces
AP-1 activation through MAPK signal transduction pathways.
Previous studies using different model systems have suggested an
important role of AP-1 activation in preneoplastic-to-neoplastic transformation in cell culture and animal models (22, 41-43). AP-1 is
a critical mediator of tumor promotion and is involved in a diversity
of processes. This transcription factor is able to alter gene
expression in response to a number of stimuli, including the tumor
promoter TPA, epidermal growth factor, tumor necrosis factor- AP-1 is a complex protein composed of homodimers and heterodimers of
oncogene proteins of the Jun and Fos families. The genes encoding these
proteins, c-jun and c-fos, are inducible in
response to a variety of extracellular stimuli and function as
intermediary transcriptional regulators in signal transduction
processes leading to proliferation and transformation. The activation
of AP-1 may trigger downstream signal cascades such as jun,
fos, and other target genes. The members of the Jun and Fos
protein families may couple cell signaling events at the cell surface
to changes in gene expression that modulate cell responses, including
proliferation and changes in phenotype. The important element of this
study is that freshly fractured silica stimulates AP-1 activation,
which may be one of the critical mechanisms in silica-induced
carcinogenesis. The level of AP-1 induction by silica was lower in RLE
cells than in JB6 cells. This may due to the following differences
between these two cell lines: (a) the rate of luciferase
gene expression, (b) the half-life of luciferase, (c) the
basal MAPK or AP-1 activities, or (d) the anti-stress enzyme activity.
The signal transduction pathways leading to transcription factor
activation have been extensively studied in the last several years. It
is believed that stress-related signals such as UV light or reactive
oxygen species induce the activation of MAPK pathways (ERKs, JNKs, and
p38). AP-1 is a downstream target of these three MAPK members (48). In
this study, the possible role of the MAPK family, including p38 kinase,
ERKs, and JNKs, in silica-induced AP-1 activation has been
investigated. We found that freshly fractured silica phosphorylated
ERKs and p38 kinase, but not JNKs. Pretreatment of cells with the p38
and ERK inhibitors PD98059 and SB203580 inhibited AP-1 transactivation
as well as AP-1 DNA binding activity induced by silica. Thus, these
results suggest that silica-induced AP-1 activation might be through
p38 MAPK and ERK pathways.
The development of AP-1-luciferase transgenic mice makes it possible to
study the role of AP-1 activation in tumor promotion in vivo
(49). The results obtained in this study show that freshly fractured
silica is able to cause AP-1 activation in transgenic mice. Maximal
AP-1 activation was increased by 23-fold in pulmonary tissues at 3 days
after intratracheal instillation of silica. However, the cell types
involved in this AP-1 activation response have not yet been identified.
Additional studies are required to answer this question.
Our studies present a model for the elucidation of events involved in
cell proliferation and carcinogenesis by crystalline silica (Fig.
9). By activating the AP-1 transcription
factor through MAPK signal transduction pathways, silica may induce
chronic cell proliferation, which subsequently contributes to silicosis
and carcinogenesis in the lung. It is possible that activation of AP-1
is a crucial event that initiates cell proliferation and progression
through the cell cycle. Biopersistent silica particles may provide
prolonged redox signals and growth stimulus during the long latency
periods of tumorigenesis and thereby contribute to the eventual
fixation of genetic changes caused by silica itself or other agents.
Furthermore, the induction of AP-1 activity may affect changes in cell
phenotype that contribute to neoplastic transformation.
In summary, using the AP-1-luciferase reporter transgenic mouse and
cell culture models, we demonstrated that freshly fractured silica
induces AP-1 activation through p38 MAPK and ERK pathways. These
studies provide new and important clues regarding molecular mechanisms
that may be involved in silica-induced carcinogenesis. Therefore,
elucidating the mechanisms involved in silica-induced carcinogenesis in
parallel with the manipulation of target signaling could provide
insights for the understanding and possible prevention of
silica-induced carcinogenesis.
*
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.
¶
To whom correspondence should be addressed: Pathology and
Physiology Research Branch, NIOSH, 1095 Willowdale Rd., Morgantown, WV
26505. Tel.: 304-285-5770; Fax: 304-385-5938; E-mail: vav1@ cdc.gov.
The abbreviations used are:
AP-1, activator
protein-1;
TPA, 12-O-tetradecanoylphorbol-13-acetate;
ERK, extracellular signal-regulated protein kinase;
MEM, minimal essential
medium;
MAPK, mitogen-activated protein kinase;
MEK, MAPK/ERK kinase;
RLE, rat lung epithelial;
FBS, fetal bovine serum;
JNK, c-Jun
N-terminal kinase.
Freshly Fractured Crystalline Silica Induces Activator Protein-1
Activation through ERKs and p38 MAPK*
,,,,, and¶
Pathology and Physiology Research Branch,
Health Effects Laboratory Division, National Institute for Occupational
Safety and Health, West Virginia 26505 and the § Hormel
Institute, University of Minnesota, Austin, Minnesota 55912
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
2) may also be generated (15, 16).
The silicon-based free radicals Si·, SiO·, and
SiOO· and the associated generation of
H2O2 and ·OH might be involved in the
lipid peroxidation and membrane damage that lead to the loss of
membrane integrity and eventual pulmonary fibrosis (12-14, 17). These
radicals are also associated with silica-induced activation of the
nuclear transcription factor NF-
B (18) and DNA damage,
e.g. strand breakage and hydroxylation of dG residues
(19).
provides a suitable
model for studying critical gene regulation events that occur during
carcinogenesis (28, 29). The signal transduction cascades involved in
AP-1 activation were also investigated. We demonstrate here that
freshly fractured silica induces AP-1 activation in both in
vivo and in vitro systems and that this activation
appears to occur through the ERK1, ERK2, and p38 kinase signal
transduction pathways.
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B) (34), was cultured in Eagle's MEM containing 5%
FBS2, 2 mM L-glutamine, and 50 µg/ml
gentamicin. The RLE cell line, stably transfected with the
AP-1-luciferase reporter plasmid (RLE/AP02), was cultured in F12K
medium containing 10% fetal calf serum and 50 µg/ml gentamicin. The
cells were grown at 37 °C in a 5% CO2 atmosphere.
B cells was trypsinized, and 5 × 104 viable
cells (suspended in 1 ml of Eagle's MEM supplemented with 5% FBS)
were added to each well of a 24-well plate. Plates were incubated at
37 °C in a humidified atmosphere of 5% CO2. Twelve hours later, cells were cultured in Eagle's MEM supplemented with 0.5% FBS for 12-24 h to minimize basal AP-1 activity and then exposed
to silica in the same medium to monitor the effects on AP-1 induction.
The cells were extracted with 200 µl of 1× lysis buffer provided in
the luciferase assay kit by the manufacturer, and the luciferase
activity was measured. The results are expressed as relative AP-1
activity compared with controls. The AP-1 activity assay for RLE/AP02
cells was similar to that described for JB6 cells, except that in RLE
cells, F12K medium containing 10% fetal calf serum was used.
0.05.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B cells were exposed to
varying doses (10~300 µg/ml) of freshly fractured silica for
24 h. Freshly fractured silica caused a significant
dose-dependent AP-1 activation in JB6 cells (Fig.
1A). The AP-1 activation
attained significance at a low silica concentration of 80 µg/ml
(
40 µg/cm2) and reached its maximum activation at 200 µg/ml (100 µg/cm2). Based on this result, 200 µg/ml silica was selected as the concentration to be used for time
course studies. At intervals from 12 to 72 h, the relative AP-1
activity was tested using the luciferase assay. Induction of AP-1
activity was first observed after 12 h of incubation; and
thereafter, AP-1 activity increased to a maximum of 8-fold activation
at 24 h (Fig. 1B). Further incubations of cells with
silica for 48 and 72 h resulted in a decrease in AP-1
activation.
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Fig. 1.
Freshly fractured silica-induced AP-1
activation in JB6 P+ cells. JB6/AP/ B cells (5 × 104 in 1 ml of MEM with 5% FBS) were seeded into each
well of a 24-well plate. After overnight culture at 37 °C, the cells
were cultured in MEM plus 0.5% FBS for 12 h. The cells were then
treated with various concentrations of silica suspended in the same
medium for 24 h (A) or with 200 µg/ml silica/well
(100 µg/cm2) for different times as indicated
(B). AP-1 activity was measured by the luciferase activity
assay as described under "Materials and Methods." The results,
presented as relative AP-1 induction compared with the untreated
control cells, are means ± S.E. of nine assay wells from three
independent experiments. *, significant increase from control
(p 0.05); 
, significant decrease from the 24-h
value (p 0.05).
150 µg/cm2), RLE cells
exhibited AP-1 levels 2.5-fold greater than those observed in control
cells. Time course studies in which a silica concentration of 200 µg/ml (100 µg/cm2) was used indicated that the time
required for maximal induction of AP-1 activity was 72 h (Fig.
2B). The AP-1 induction in RLE/AP02 cells was different from
that observed in JB6 cells. In RLE cells, the induction of AP-1
activity in response to silica occurred more slowly and persisted for
at least 72 h. The level of AP-1 induced by freshly fractured
silica was lower in RLE cells than in JB6 cells. Because JB6 cells
respond to a greater degree than RLE cells, JB6 cells were chosen for
further studies.
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Fig. 2.
Induction of AP-1 activity in RLE cells.
RLE/AP02 cells (5 × 104 cells in 1 ml of F12K medium
containing 10% of FBS), stably transfected with the AP-1-luciferase
reporter plasmid, were seeded into each well of a 24-well plate. After
overnight culture at 37 °C, the cells were cultured in F12K medium
plus 0.5% FBS for 12 h. The cells were then exposed to various
concentrations of silica suspended in the same medium for 72 h
(A) or 200 µg/ml silica/well (100 µg/cm2)
for different times as indicated (B). Other experimental
conditions were the same as those described in the legend to Fig. 1.
The results, presented as relative AP-1 induction compared with the
untreated control cells, are means ± S.E. of 12 assay wells from
three independent experiments. *, significant increase from control
(p 0.05).
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Fig. 3.
Freshly fractured silica induces the
transactivation of AP-1 in AP-1-luciferase reporter transgenic
mice. The AP-1-luciferase transgenic mice were intratracheally
instilled with 5 mg of freshly fractured silica suspended in 0.07 ml of
0.9% sterile saline. At 2, 3, or 4 days post-exposure, the mice were
sacrificed, and the lung tissue was removed. The luciferase activity of
the tissue was measured as described under "Materials and Methods."
The results, presented relative to the level of luciferase activity of
the control groups, are means ± S.E. of eight mice. *,
significant increase from controls; **, significant increase from 2 days post-exposure; , significant decrease from 3 days post-exposure
(p 0.05).
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Fig. 4.
Freshly fractured silica stimulates the
phosphorylation of p38 MAPK. JB6 P+ cells were
cultured in MEM containing 5% FBS in six-well (35-mm diameter) plates
until 80% confluent and then cultured in MEM containing 0.5% FBS for
24 h. After this time, the cells were exposed to 150 µg/ml
silica (47 µg/cm2) suspended in the same medium for
different times as indicated (A) or to various
concentrations of silica for 2 h (B). The cells were
lysed, and phosphorylated and non-phosphorylated p38 kinase proteins
were assayed using the PhosphoPlus MAPK kit. The phosphorylated and
non-phosphorylated proteins were analyzed using the same transferred
membrane blot.
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Fig. 5.
Freshly fractured silica induces activation
of ERK1 and ERK2. JB6 P+ cells were cultured in MEM
containing 5% FBS in six-well (35-mm diameter) plates until 80%
confluent. The cells were cultured in MEM containing 0.5% FBS for
24 h and then exposed to 150 µg/ml silica (47 µg/cm2) suspended in the same medium for different times
as indicated. The cells were lysed, and phosphorylated ERK1 and ERK2
proteins and non-phosphorylated ERK2 proteins were assayed using the
PhosphoPlus MAPK kit. The phosphorylated and non-phosphorylated
proteins were analyzed using the same transferred membrane blot.
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Fig. 6.
Effect of freshly fractured silica on JNK
activity. JB6 P+ cells were cultured in MEM containing
5% FBS in six-well (35-mm diameter) plates until 80% confluent. The
cells were cultured in MEM containing 0.5% FBS for 24 h and then
exposed to 150 µg/ml silica (47 µg/cm2) suspended in
the same medium for different times as indicated. The cells were lysed,
and phosphorylated and non-phosphorylated JNK proteins were assayed
using the PhosphoPlus MAPK kit.
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Fig. 7.
Inhibition of silica-induced AP-1 activation
by PD98059 and SB203580. JB6 cells (5 × 104)
were seeded into each well of a 24-well plate. After overnight culture
at 37 °C, the cells were cultured in MEM plus 0.5% fetal bovine
serum for 12 h. The cells were then pretreated with various
concentrations of the ERK inhibitor PD98059 (A) or the p38
inhibitor SB203580 (B) for 2 h and exposed to 150 µg/ml silica in the presence of the inhibitors for 24 h. AP-1
activity was measured by the luciferase activity assay as described
under "Materials and Methods." The results, presented as relative
AP-1 induction compared with the control cells, are means ± S.E.
of 12 assay wells from two independent experiments. *, significant
increase from untreated controls; **, significant decrease from silica
alone (p 0.05).
View larger version (66K):
[in a new window]
Fig. 8.
Electrophoretic mobility shift
assay. JB6 cells were seeded into each well of a six-well
plate until 80% confluent. The cells were then cultured in MEM plus
0.5% fetal bovine serum for 24 h. The cells were pretreated with
20 µM PD98059 or 5 µM SB203580 for 2 h
and then exposed to 150 µg/ml silica in the presence of the
inhibitors for another 2 h. The AP-1 DNA binding activity was
determined by gel shift assay as described under "Materials and
Methods."
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
,
interleukin-1, and UV irradiation (22). Some of the genes regulated by
AP-1 are involved in immune and inflammatory responses, tumor
promotion, and tumor progression. These include cytokines such as
interleukin-1, tumor necrosis factor-, granulocyte-macrophage colony-stimulating factor, collagenase IV, and stromelysin (44-46). Overexpression of c-jun in JB6 P+ cells causes
neoplastic transformation. Inhibition of AP-1 activity by either
pharmaceutical agents such as fluocinolone acetonide and retinoic acid
or molecular biological inhibitors such as dominant-negative c-jun and dominant-negative phosphatidylinositol 3-kinase
was found to block tumor promoter-induced neoplastic transformation (25, 31, 34, 41, 42, 47).
View larger version (13K):
[in a new window]
Fig. 9.
Mechanistic schema of events in
silica-induced carcinogenesis.
FOOTNOTES
ABBREVIATIONS
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MATERIALS AND METHODS
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