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J Biol Chem, Vol. 275, Issue 20, 15549-15556, May 19, 2000
From the cAMP-mediated cell proliferation is a
complex process that involves multiple pathways. Using a
cAMP-dependent cell system, FRTL-5 thyroid cells, we have
previously demonstrated the existence of a precise autocrine loop in
the control of cell proliferation that involves the positive effector
thyrotropin (TSH) and the general inhibitor somatostatin. In search of
the regulatory mechanisms responsible for the TSH and somatostatin
control of cell proliferation, we analyzed the cell cycle regulatory
proteins and the cellular pathways involved in the action of both
signals. The results show that specific inhibition of
cAMP-dependent protein kinase (PKA) and
phosphatidylinositol (PI) 3-kinase blocks independently TSH-induced FRTL-5 cell proliferation and that somatostatin interferes with both
signals. Each pathway activates different proteins required for
G1/S progression. Thus, PKA is responsible for the
TSH-induction of 3-hydroxy-3-methylglutaryl-CoA reductase mRNA
levels, RhoA activation, and down-regulation of p27kip1. These
correlated events are necessary for FRTL-5 cell proliferation after TSH
stimulation. Moreover, TSH through PKA pathway increases cyclin-dependent kinase 2 levels, whereas PI 3-kinase
signaling increases cyclin E levels. Together, both pathways finally
converge, increasing the formation and activation of cyclin
E·cyclin-dependent kinase 2 complexes and the
phosphorylation of the retinoblastoma protein, two important steps in
the transition from G1 to S phase in growth-stimulated
cells. Somatostatin exerts its antiproliferative effect inhibiting more
upstream the TSH stimulation of PKA and PI 3-kinase, interfering with
the TSH-mediated increases of intracellular cAMP levels by inactivation
of adenylyl cyclase activity. Together, these results suggest the
existence of a PKA-dependent pathway and a new
PKA-independent PI 3-kinase pathway in the TSH/cAMP-mediated proliferation of FRTL-5 thyroid cells.
Cell cycle progression in mammalian cells requires the coordinated
action of several classes of cyclin-dependent kinases
(Cdk)1 and cyclin complexes.
One of the critical targets of cyclin·Cdk complexes is the
retinoblastoma (Rb) gene product, which acts as a transcriptional
repressor. During G1 phase, Rb is hypophosphorylated and
binds to E2F, a family of cell cycle transcription factors, inhibiting
its activity. Rb is inactivated by a coordinated, sequential phosphorylation by cyclin D·Cdk4, cyclin D·Cdk6 in
mid-G1 phase, and cyclin E·Cdk2 in the G1/S
boundary (which completes the phosphorylation of Rb in additional
sites) (for review see Refs. 1-3). This process leads to Rb
dissociation from E2F, with the corresponding activation of genes
containing E2F-binding sites in their promoters and implicated in
G1/S transition (for review see Refs. 5 and 6). Another level of Cdk activity regulation results from the action of Cdk inhibitors that bind to cyclin·Cdk complexes and either inhibit their
kinase activities or prevent their activation by Cdk-activating kinases
(for review see Refs. 5 and 6). The Cdk inhibitors comprise two classes
of proteins. The first includes the Ink4 family, so named for their
ability to inhibit specifically the catalytic subunit of Cdk4 and Cdk6.
The second class includes the Cip/Kip family, which can interact with
many different cyclin·Cdk complexes. This family was initially
described to interfere with the activity of cyclin D-, E-, and
A-dependent kinases. More recent work revealed that
although the Cip/Kip proteins are potent inhibitors of cyclin E- and
A-dependent Cdk2, they can act as positive regulators of
cyclin D·Cdk4 and Cdk6 complex formation (4, 7). In this last Cdk
inhibitor family, p27kip1 is a widely distributed Cdk inhibitor
that has an important role in regulating entry into and exit from the
cell cycle.
We have recently demonstrated that p27kip1 expression is
down-regulated by thyrotropin (TSH) in FRTL-5 thyroid cells and that somatostatin prevents this TSH-induced down-regulation (8). FRTL-5
cells provide an excellent system to study the mechanisms that govern
progression from G1 to S phase, because in this cell type
the transition from quiescent to proliferative cells requires the
action of hormones and growth factors such as TSH, insulin, and
insulin-like growth factor-I (9-12). Studies in FRTL-5 thyroid cells,
although performed in different hormonal backgrounds, show that TSH
increases the expression of G1 cyclins such as cyclin D1,
D3, and E (13, 14) as well as its partners Cdk2 and Cdk4 (13, 15).
Moreover, these effects correlate with down-regulation of
p27kip1 protein levels (8, 13) and with an increase in the
phosphorylation state of Rb (13), leading to the activation of
cyclin·Cdk complexes and the progression of the cells through the
cell cycle. TSH cell cycle induction is counteracted by cytostatic
signals such as TGF- The critical role of p27kip1 in the cytostatic effects elicited
by somatostatin (8, 18) is the focus of our present study. Among other
functions, p27kip1 has been implicated in G1 arrest
induced by inhibitors of 3-hydroxy-3-methylglutaryl-coenzyme A
(HMG-CoA) reductase (19, 20). These inhibitors interfere with cell
cycle progression by suppressing the isoprenylation of proteins
(21-23). A class of isoprenylated small GTP-binding proteins, termed
Rho small GTPases, is proposed to be involved in G1/S
transition in mouse fibroblasts (24) and also in FRTL-5 thyroid cells
(15). RhoA, a member of a subgroup of the Ras superfamily, regulates a
wide spectrum of cell functions such as cell growth, membrane
trafficking, and transcription (for review see Ref. 25). RhoA
expression promotes p27kip1 degradation in FRTL-5 cells,
leading to progress from G1 to S phases (15). In addition,
p27kip1 is involved in G1 arrest by cAMP, in cells
in which this second messenger is an inhibitor of cell proliferation
(26, 27); conversely, cAMP signaling in FRTL-5 cells is the main
mediator of thyroid cell proliferation in response to TSH (28).
We have studied how this hormone regulates two important mediators of
the G1-S transition (Cdk2 and cyclin E associated with p27kip1), as well as the role played by somatostatin in each
control point of the TSH effect. Our work focused on the effect of TSH alone. The results obtained are due to TSH and not to the combined action of TSH with other hormones and growth factors, such as insulin
or serum. The main signal pathways involved in TSH and somatostatin
control of cell growth have been also studied. The results show that
TSH regulates cell cycle proteins through at least two independent
pathways that involve PKA and PI 3-kinase. These pathways induce
different sets of cell cycle proteins that finally converge in Rb
phosphorylation. Somatostatin prevents TSH modulation of
p27kip1·Cdk2 association, cyclin E·Cdk2 kinase activity,
and the phosphorylation of Rb. Moreover, somatostatin also blocks the
TSH-mediated induction of HMG-CoA-reductase mRNA levels as well as
RhoA activation, two of the decisive events in FRTL-5 cells growth,
which we show are mediated by PKA but not by PI 3-kinase. Finally, the
mechanism by which somatostatin interferes with TSH effects involves
inhibition of the adenylyl cyclase activity and the consecutive
decrease in TSH-induced intracellular cAMP levels.
Materials--
Tissue culture medium, bovine TSH, somatostatin,
and bovine insulin were purchased from Sigma. H89, PD98059, wortmannin,
and anti-Rb antibody were from Calbiochem. Octeotride (sandostatin) was
from Sandoz Pharma Ltd. The Luminol kit, streptavidin-horseradish peroxidase conjugate, anti-Cdk2, anti-cyclin E, and anti-p27 antibodies were from Santa Cruz Biotechnology. Histone H1 was from Roche Molecular
Biochemicals. Pravastatin was a gift from Bristol-Myers Squibb. Donor
calf serum was from Life Technologies, Inc., and Nytran and
nitrocellulose filters were from Schleicher & Schuell. The Biotrak cAMP
enzyme immunoassay system (dual range) prestained protein marker,
[ Cell Culture--
FRTL-5 thyroid cells (29) were cultured in
Coon's modified Ham's F-12 medium supplemented with 5% donor calf
serum and a hormone mixture (6H medium) including
glycyl-L-histidyl-L-lysine acetate (10 ng/ml),
hydrocortisone (10 nM), transferrin (5 µg/ml), somatostatin (10 ng/ml), insulin (10 µg/ml), and TSH (1 nM). Fresh medium was added every 2 or 3 days, and cultures
were divided every 7 days. Before treatment, cell cultures were
maintained for 3 days (otherwise indicated) in medium depleted of TSH,
insulin, somatostatin, and 0.2% serum (3H medium) and were then
maintained with each treatment at the concentration and for the time
indicated below. Cells maintained in 3H medium (8) are completely
viable.2
To perform growth curve profiles FRTL-5 cells (4 × 104) were maintained in basal medium (3H) for 3 days and
then treated with TSH (1 nM), somatostatin (1 µM), octeotride (100 ng/ml), H89 (10 µM),
PD98059 (50 µM), wortmannin (25 nM), or
pravastatin (100 µg/ml) in the combinations indicated for each
experiment. To avoid wortmannin degradation, this inhibitor was added
every 6 h to cell culture medium. The number of viable cells was
determined by cell counting at 36 h (otherwise indicated), and the
means ± S.D. of three independent experiments are represented.
Northern Blot Analysis--
Total RNA was isolated by the
guanidinium-isothiocyanate-phenol procedure (30). Samples of total RNA
were electrophoresed in 1% agarose gels containing formaldehyde. RNA
was transferred to Nytran membranes, and RNA integrity was revealed by
methylene blue staining of the blots. Hybridization and washing were
performed with a probe specific for HMG-CoA reductase (31) and labeled with [ Transient Transfections and Flow Cytometric Analysis--
FRTL-5
cells grown to 80% confluence in 6H medium were transiently
transfected (8) with 10 µg of different expression vectors. The
involvement of PI 3-kinase pathway was studied with the constitutively activated catalytic subunit (p110CAAX) or the dominant negative (p Western Blots and Immunoprecipitation Assays--
Total protein
extracts (50 or 90 µg for Rb detection) were subjected to 7.5, 10, and 12% SDS-polyacrylamide gel electrophoresis, for Rb, cyclin E and
Cdk2, and p27kip1 and RhoA respectively, and the proteins were
transferred to nitrocellulose membranes. Membranes were blocked for
1-2 h at room temperature in TBS-T buffer (20 mM Tris-HCl,
137 mM NaCl, 0.1% Tween-20, pH 7.5) containing 5% non-fat
milk. After incubation with the corresponding antibodies (1 µg/ml,
1 h, room temperature) in TBS-T containing 5% non-fat milk,
membranes were washed three times with TBS-T and then incubated with a
1:5000 dilution of streptavidin-horseradish peroxidase conjugate,
followed by three washes of 5 min/each with TBS-T buffer.
Immunoreactive bands were visualized using the Luminol kit as described
by the manufacturer. RhoA levels were quantitated after densitometric
scanning of the blots using the MacBas software.
For immunoprecipitation assays we used the IMMUNOcatcher kit. Briefly,
cells were lysed as recommended by the manufacturer, and 500 µg of
total protein extracts were incubated with the primary antibody (1 h,
room temperature). The samples were then incubated for 30 min at room
temperature with 20 µl of protein A/G-Sepharose. After
centrifugation, the pellets were washed three times in lysis buffer,
resuspended in 40 µl of protein sample buffer, separated in
SDS-polyacrylamide gel electrophoresis, and transferred to nitrocellulose membranes.
Histone H1 Kinase Assay--
Cell lysis and immunoprecipitation
were performed as described above. After washing in lysis buffer,
pellets were resuspended in 40 µl of kinase buffer (20 mM
HEPES, pH 7.4, 5 mM Na3VO4, 10 mM MgCl2, 25 mM EGTA, 10 mM cAMP Assays--
The Biotrak cAMP competitive enzyme immunoassay
system was used, following the manufacturer's instructions. Briefly,
FRTL-5 cells were grown in 96-well microtiter plates
(104-106 cells/ml), maintained in 3H medium
for 3 days, and then treated with 1 nM TSH, 1 µM somatostatin, 100 ng/ml octeotride, or the appropriate
combination for 0.5, 1, 2.5, or 4 h. Cells were then lysed, moved
to a donkey anti-rabbit Ig precoated microtiter plate, and incubated
with anti-cAMP antiserum for 2 h at 4 °C, after which samples
were incubated with a cAMP-peroxidase-conjugated antibody (1 h,
4 °C) and washed four times with washing buffer. The enzyme
substrate was added immediately afterward to all wells and incubated (1 h, room temperature). Prior to optical density determination a plate
reader at 450 nm, the reaction was terminated by adding 1 M
sulfuric acid to each well. In parallel, we prepared a standard curve
with concentrations cAMP from 12.5-3200 fmol/well. Each value
represents the mean ± S.D. of three different experiments.
Adenylyl Cyclase Assays--
Cells in 10 mM
Tris-HCl, pH 7.5, and 0.1 mM EDTA were homogenized at
0-4 °C by nitrogen cavitation using a 75 ml of Parr bomb; cells
were equilibrated for 15 min at 750 p.s.i. N2,
followed by slow release into a glass test tube. The homogenates were
centrifuged (500 × g, 10 min) to remove nuclei and
unbroken cells. Membranes were collected by centrifugation of the
supernatant fluid (18,000 × g, 10 min), washed in 10 volumes of the same buffer, recentrifuged, resuspended in the same
buffer (1-2 mg of protein/ml), and stored in aliquots at PKA and PI 3-kinase Are Involved in TSH-induced FRTL-5 Thyroid Cell
Proliferation--
We previously described the existence of an
autocrine loop in the control of FRTL-5 thyroid cell proliferation that
involves TSH, the main regulator of thyroid cell proliferation, and
somatostatin, a cytostatic agent (8). To elucidate the signal
transduction pathways mediating TSH proliferation and the level at
which somatostatin elicited its negative control, FRTL-5 cells were
maintained for 3 days in a medium containing 0.2% serum and depleted
of TSH, insulin, and somatostatin (3H medium). The cells were then
treated for 36 h with TSH alone or combined with specific
inhibitors of the most common transduction signal pathways or with
somatostatin as described under "Experimental Procedures." Growth
curve profiles (Fig. 1A) and
cell cycle distribution after flow cytometric analysis (Fig.
1B) were determined. TSH increased cell number about
1.7-fold, and when added together with somatostatin, a detectable
inhibition of cell number was observed. The most drastic inhibition of
TSH induction of cell growth was obtained with the PKA inhibitor H89. A
PI 3-kinase inhibitor, wortmannin, also inhibited TSH cell growth induction, although to a lesser extent than H89. The inhibitor of MEK
(the upstream regulator of mitogen-activated protein kinase) PD98059
had no effect on TSH induction of cell growth in 3H cells. The results
of G1/S ratio analysis are summarized in Fig.
1B. Cells maintained in 3H medium have an increase in
G1 over the S phase that indicates cell quiescence, with a
virtual absence of DNA synthesis. TSH treatment of quiescent 3H cells
clearly promotes G1 transition to S phase, and the
G1/S ratio decreases 75%. When the cells were treated with
TSH plus somatostatin, H89, or wortmannin, however, accumulation was
detected in G1 phase, with a G1/S ratio similar
to that observed in quiescent 3H cells. Again, PD98059 treatment had no
effect on cell cycle distribution.
The involvement of PI 3-kinase in the TSH induction of FRTL-5 cells
growth is very interesting and has not been previously reported in this
cell line. Because of the relevance of these data, we confirm our
observation using another experimental approach. FRTL-5 cells
maintained in 6H medium were transiently transfected with an expression
vector encoding a dominant negative of PI 3-kinase (32). Control cells
were transfected with the empty vector. After transfection, cells were
maintained for 36 h in 3H medium and then treated with TSH for
other 36 h. In all transfection experiments, a plasmid containing
GFP was cotransfected to normalize transfection efficiency, and then
cytometric analysis was performed. The results show that control cells
respond to TSH and have a cell cycle profile indicative of cells
progressing through the G1/S phase (G1/S: 7.1),
whereas cells expressing the dominant negative of PI 3-kinase do not
respond to TSH and have a dramatic decrease in the S phase
(G1/S: 12.9) (Fig. 1C). When an expression vector of the constitutively activated catalytic subunit of PI 3-kinase
(32) was transfected in the same conditions as above, the cells respond
to TSH and have a curve profile similar to control cells (data not shown).
Together all these data confirm two previous observations demonstrating
that (i) TSH alone, in the absence of growth factors (0.2% serum) and
insulin (3H medium), can induce thyroid cell growth (8, 40), and (ii)
somatostatin elicits a cytostatic effect (8). These data also
demonstrate that TSH regulation of cell growth involves at least two
cascades, one via PKA and another via PI 3-kinase.
TSH Regulates Cell Cycle Proteins Required to G1/S
Transition--
Once two of the main signal transduction pathways
mediating TSH induction of FRTL-5 cell growth had been determined, we
analyzed the cell cycle proteins involved in this response and, more
precisely, those at the G1-S boundary. Cells maintained for
3 days in 3H medium (0 h) were treated with TSH for 12, 24, and 36 h, and Western blots for Cdk2, cyclin E, and p27kip1 proteins
were performed. Cdk2 and cyclin E levels increased with TSH in a
time-dependent manner (Fig.
2A), whereas the levels of the
Cdk-dependent kinase inhibitor p27kip1 decreased in
parallel. Following the same experimental approach, TSH was added for
36 h to quiescent 3H cells, alone or together with somatostatin,
H89, or wortmannin. Somatostatin decreased the TSH-mediated
up-regulation of both Cdk2 and cyclin E proteins, and, as we have
described previously (8), it also decreases TSH-mediated
down-regulation of p27kip1 (Fig. 2B, lane
3). We observe some differences when comparing the effects of PKA
and PI 3-kinase inhibitors. H89 decreases TSH up-regulation of Cdk2,
inhibits TSH down-regulation of p27kip1, and has no effect on
cyclin E levels (Fig. 2B, lane 4). Conversely, wortmannin only has an effect on cyclin E, decreasing its TSH up-regulation, but does not modify the TSH-regulated Cdk2 and p27kip1 levels (Fig. 2B, lane 5). These
results indicate that the two main pathways that mediate TSH effect on
FRTL-5 cell proliferation, PKA and PI 3-kinase, diverge in the
regulation of these cell cycle proteins. PKA thus mediates the
regulation of Cdk2 and p27kip1, whereas PI 3-kinase is involved
in cyclin E regulation. Furthermore, somatostatin interferes with all
of these effects, suggesting that its mechanism of action lies further
upstream.
Somatostatin Decreases TSH-mediated Activation of Cyclin E·Cdk2
Complexes and Retinoblastoma Phosphorylation--
The kinase activity
of the cyclin E·Cdk2 complexes was then analyzed. We first studied
the formation of cyclin E·Cdk2 complexes, and as predicted, the
results demonstrate that TSH increases total Cdk2 protein levels as
well as the cyclin E bound to it (Fig. 3A, lane 2).
Somatostatin affects the complex formation inhibiting the
TSH-dependent increase of Cdk2 and cyclin E (Fig.
3A, lane 3; see also Fig. 2B,
lane 3). The specific inhibitors of PKA and PI 3-kinase
affect complex formation in a different way. Thus, H89 decreases the
Cdk2 protein immunoprecipitated (Fig. 3A, lane 4), whereas wortmannin only affects the complex by inhibiting the
cyclin E protein levels (Fig. 3A, lane 5; see
also Fig. 2B, lane 5). We also determined the
activity of these complexes using the H1 kinase assay. Cdk2 activity is
maximal in the TSH-treated group (Fig. 3A, bottom
panel); no activity is detected in the other groups, except for
wortmannin-treated cells, in which residual activity is observed. This
effect is probably due to a small amount of p27kip1 bound to
Cdk2 in this group (Fig. 3B, lane 5). As seen in
this panel, when p27kip1 was immunoprecipitated and probed with
p27-specific antibodies, we observed that p27kip1 was almost
undetectable in TSH-treated cells (lane 2). In the rest of
the groups, p27kip1 levels are very similar, except for the
cells treated with wortmannin. These results indicate that most
p27kip1 is degraded in the group treated with TSH, so that
cyclin E·Cdk2 should be free to phosphorylate its substrates, as
shown above in the H1 kinase assay.
We next performed Western blot assays with a specific anti-Rb antibody.
This antibody detects the active hyperphosphorylated form of the
protein (Fig. 3C, upper band) as well as the
inactive, more slowly migrating hypophosphorylated form (lower
band). In quiescent 3H cells, Rb is expressed at very low levels
(Fig. 3C, lane 1). TSH increased Rb protein
levels as well as its phosphorylation state, seen as an
increase in the upper phosphorylated band (Fig. 3C,
lane 2). Conversely, somatostatin, H89, and wortmannin inhibited the TSH-induced phosphorylation of Rb protein (Fig. 3C, lanes 3-5). These data suggest that Rb could
be the main inhibition mechanism of G1/S transition in our
study of FRTL-5 thyroid cell growth.
Somatostatin Inhibits the TSH Induction of HMG-CoA
Reductase--
To study the signaling circuits involved in the TSH and
somatostatin regulation of p27kip1 levels, we tested the
regulation of HMG-CoA reductase, because p27kip1 has been
implicated in the G1 arrest induced by an inhibitor of this
enzyme (19, 20). Using Northern blot assays (Fig. 4A), we show that, in cells
maintained in 3H medium, HMG-CoA reductase mRNA levels are
undetectable (lane 1). TSH can increase these levels
(lane 2), as has been previously demonstrated (31).
Somatostatin (lane 3) and H89 (lane 4) block this
TSH increase, as does the inhibitor of HMG-CoA reductase, pravastatin
(lane 5). Wortmannin had no effect on TSH induction of
HMG-CoA reductase, indicating that TSH induces the expression of this
enzyme mainly via the PKA pathway. When pravastatin was added alone, in
the absence of TSH induction, HMG-CoA-reductase mRNA levels were
undetectable as observed in 3H group (data not shown). To confirm the
importance of HMG-CoA reductase in TSH-mediated proliferation, growth
curves and cytometric assays were performed in parallel studies.
Pravastatin decreases the TSH induction of cell number (Fig.
4B) as well as the TSH decrease of G1/S ratio
(Fig. 4C). These two experimental approaches clearly confirm
that inhibition of isoprenoid synthesis promotes G1 arrest
in FRTL-5 cells and further demonstrate that TSH regulation of HMG-CoA
reductase is mediated by PKA and not by the PI 3-kinase pathway.
RhoA Is Required for TSH-induced G1
Progression--
Because HMG-CoA reductase activity is necessary to
isoprenylate small GTPases and RhoA is reported to be essential for the degradation of p27kip1, facilitating G1/S
progression in FRTL-5 cells (15), we studied the role of this small
GTPase in TSH-induced G1 progression. We first determined
whether RhoA is activated by TSH alone and/or this activation is
inhibited by somatostatin, H89, wortmannin, or pravastatin. For this
purpose, Western blot was performed with a specific anti-RhoA antibody,
using fractionated proteins derived from the above experimental groups
(Fig. 5A). After quantitation of the RhoA levels in membrane and cytosolic fractions (Fig.
5B), we show that RhoA is activated by TSH, because this
hormone induces the translocation of RhoA from the cytoplasm to the
membrane. Somatostatin, pravastatin, and the PKA inhibitor, but not the PI 3-kinase inhibitor, blocked TSH induction of RhoA activation.
To confirm the role of RhoA in FRTL-5 cell cycle, transfection
experiments were performed with expression vectors encoding the
cDNA of a dominant positive RhoA QL (32), the botulinum C3
exoenzyme TC3 (34), which specifically inactivates Rho proteins (41),
or the dominant negative RhoA N19 (33). Control cells were transfected
with the empty vector. In all transfection experiments, a plasmid
containing GFP was cotransfected to normalize transfection efficiency,
and transfected cells were analyzed cytometrically. The results (Fig.
5C) show that cells overexpressing RhoA have a cell cycle
profile similar to FRTL-5 control cells progressing through the
G1/S phase. When RhoA was inactivated with TC3, cells suffered arrest in G1, similar to that found when the
dominant negative RhoA N19 was overexpressed. These data demonstrate
that inactivation of RhoA is sufficient to arrest FRTL-5 cells in
G1 phase, revealing its importance in cell cycle control.
Moreover, we demonstrate that TSH, probably through PKA and by
activation of HMG-CoA reductase, induces RhoA translocation to the
plasma membrane. Finally, we show that somatostatin is again able to counteract this effect of TSH.
Somatostatin Inhibits TSH Induction of FRTL-5 Cell Proliferation by
Interfering with Adenylyl Cyclase Activity--
The results presented
thus far show that somatostatin is able to inhibit most TSH-induced
effects on FRTL-5 cell proliferation. This suggests that somatostatin
inhibition would involve a mechanism upstream of the signal
transduction pathways stimulated by TSH. As we previously reported (8),
somatostatin action on FRTL-5 cell growth is mediated through its
specific receptor, SSTR2. Previous work has demonstrated that this
receptor is coupled to adenylyl cyclase, inhibiting cAMP production
(42). TSH, after binding to its own receptor, increases the
intracellular levels of cAMP activating the PKA (28). This evidence
suggests a plausible mechanism of somatostatin action through its SSTR2
receptor by inhibiting TSH induction of intracellular cAMP levels and
the consecutive inhibition of PKA and PI 3-kinase pathways. To test this hypothesis, we used two different approaches. We determined the
intracellular cAMP levels and the adenylyl cyclase activity in FRTL-5
cells maintained in basal 3H medium or treated with TSH alone or
together with somatostatin for different periods of time and at various
concentrations. The results demonstrate that TSH stimulates
intracellular cAMP levels with respect to those observed in cells
maintained in 3H medium (Fig.
6A). This stimulation occurs
in a time-dependent manner (not shown), with maximum
stimulation after 2 h of treatment. In parallel, TSH stimulates adenylyl cyclase activity (Fig. 6B); conversely,
somatostatin abolished TSH induction of cAMP (Fig. 6A). This
effect was mimicked by a somatostatin analog, octeotride, that also
acts through the SSTR2. Interestingly, somatostatin inhibits TSH
induction of the adenylyl cyclase in a dose-dependent
manner (Fig. 6B). These data demonstrate that somatostatin
interference with TSH action already occurs in the first step of TSH
signaling.
The control of cell proliferation requires a balance between
positive effectors and cytostatic signals. In the case of FRTL-5 thyroid cells, we have recently demonstrated (8) that this control is
elicited by an autocrine loop that involves TSH, as a positive
effector, and somatostatin, as a cytostatic agent. Although it is
widely accepted that cAMP is the main mediator of TSH stimulation of
thyroid cell growth (28, 43), increasing evidence suggests that the
mechanism of TSH action involves more than the PKA classical signal
transduction pathway (44). In different thyroid cell systems and with
different hormonal backgrounds, TSH is able to activate PKA (28),
protein kinase C (45, 46), and mitogen-activated protein kinase (47),
inducing distinct thyroid cell functions. Most the studies were
performed in FRTL-5 cells, and in most of them, TSH action has been
analyzed in the presence of permissive factors such as
insulin/insulin-like growth factor-I or serum growth factors (48).
Insulin per se thus promotes moderate increases in protein
and DNA synthesis in FRTL-5 and PC13 thyroid cells (49), as well as
increases in G1 cyclins, D1 and E (14). Moreover, in many
studies, TSH effects on proliferation are masked by the presence of
somatostatin in the culture medium (8). For this reason, we focused on
the signal transduction pathways and the cell cycle progression
mediated by TSH alone, in the absence of any other ligand, as well as
the negative role elicited by somatostatin on TSH action. Our results
show that specific inhibition of PKA and PI 3-kinase independently
blocks TSH-induced FRTL-5 cell proliferation and that somatostatin
interferes with both signals. Our data inhibiting MEK, the upstream
regulator of mitogen-activated protein kinase, confirm previous results in dog thyrocytes (50) and Wistar rat thyroid cells (47), showing that
the mitogen-activated protein kinase pathway is not involved in
TSH-mediated proliferation. Although it has been described that TSH
induces protein kinase C activation (45, 46), we did not study the
participation of this kinase in TSH-induced FRTL-5 proliferation,
because such activation has been observed under unusual culture
conditions, with high doses of TSH, insulin, and serum in the medium.
In summary, our results suggest that the proliferative response of TSH
in FRTL-5 cells involves at least two independent pathways, PKA and PI
3-kinase. During the preparation of this manuscript, Cass et
al. (44) demonstrated, in Wistar rat thyroid cells, that the
mitogenic signals initiated by cAMP diverge to include
PKA-dependent pathways, leading to p70s6
kinase, and PKA-independent pathways that regulate Akt and Rac1 via PI
3-kinase. These observations corroborate our results on the implication
of the PI 3-kinase pathway in TSH-induced cell growth, suggesting
TSH/cAMP-dependent induction of the PI 3-kinase signal. We
have also observed that TSH increases p70s6 kinase protein
levels in FRTL-5 and that this activation is PKA-dependent and PI 3-kinase-independent.2
To link the proliferative TSH-stimulated pathways with the cell cycle
machinery, we determined the effects of PKA and PI 3-kinase inhibition
on the cell cycle proteins necessary for G1/S transition. The main regulators of this transition are the G1 cyclins
(D and E) and their partner cyclin-dependent kinases
(Cdk-2, Cdk-4, and Cdk-6). The most recognized function of cyclin
D-dependent kinase is phosphorylation of Rb, which
initiates in mid-G1 phase; thereafter, cyclin E·Cdk2
becomes active and completes this process by phosphorylating Rb on
additional sites. Although we focused our study on the late G1 phase, mediated mainly by cyclin E·Cdk2 complexes,
several pieces of evidence suggest that cyclin D·Cdk-4 and Cdk-6 must be also active in TSH-stimulated FRTL-5 cells: first, our previous results indicated TSH up-regulation of cyclin D1 (8), and second, the
TSH-mediated increase in Rb phosphorylation observed here. Our results
furthermore demonstrate that TSH increases cyclin E and Cdk-2 as well
as down-regulates p27kip1 protein levels. These effects are
differentially mediated by PKA, which is responsible for the TSH
increases of Cdk-2 and p27kip1 down-regulation, and PI
3-kinase, which is necessary for TSH increases of cyclin E. TSH also
increases Rb protein levels and its phosphorylated state, whereas PKA
and PI 3-kinase inhibitors revert this effect, indicating that both
pathways converge in the nucleus, leading finally to the Rb
phosphorylation. These results indicate that PI
3-kinase-dependent increases in cyclin E might be explained
in light of the recent view of G1-S progression control
(4). PI 3-kinase is thus involved in the turnover of D-type
cyclins. Inhibition of this pathway increases cyclin D1 degradation
(51), with the consequent inhibition of Rb phosphorylation and
E2F-dependent cyclin E transcription. Conversely,
somatostatin inhibits both the TSH increases of cyclin E and Cdk-2 as
well as TSH down-regulation of p27kip1. As expected, it also
inhibits cyclin E·Cdk2 complexes, decreasing the amount of Cdk-2
immunoprecipitated and increasing the p27kip1 bound to the
complex and the TSH phosphorylation of Rb.
p27kip1 promotes G1 arrest induced by inhibitors of
HMG-CoA reductase, a rate-limiting enzyme in the synthesis of
isoprenoids. A class of isoprenylated small GTPase, RhoA, is involved
in G1/S progression in FRTL-5 cells (15). Our results
confirm that TSH increases HMG-CoA reductase mRNA (31) and also
demonstrate that somatostatin inhibits this up-regulation. In addition,
the inhibition of HMG-CoA reductase activity promotes cell cycle
arrest, confirming the important role of this enzyme in TSH-induced
proliferation. The activity of this enzyme is PKA-dependent
and PI 3-kinase-independent. The latter results correlate with an
increase in RhoA levels in the membrane fraction of TSH-stimulated
FRTL-5 cells; somatostatin, H89, and pravastatin, but not wortmannin,
inhibit this effect, suggesting that PKA may activate RhoA in FRTL-5
cells. The mammalian Rho family of GTPases, including RhoA, Rac1, and
Cdc42, plays a pivotal role in controlling many cellular functions
including cell polarity, motility, proliferation, apoptosis, and
cytokinesis (25). In other cell types, such as neural cells and
lymphocytes, RhoA can be specifically phosphorylated at Ser-188 by PKA.
This decreases the binding of RhoA to downstream effectors, suggesting that RhoA and cAMP have antagonistic regulatory roles in these cells
(52). The role of cAMP is completely different in the thyroid, however;
this second messenger thus activates a proliferative response in the
majority of thyroid cell systems (11, 53, 54). In FRTL-5 thyroid cells,
RhoA activation is essential for p27kip1 degradation and the
consequent G1/S progression; this activation is HMG-CoA
reductase-dependent (15). In addition, we show that overexpression of an interfering mutant (RhoA N19) or a specific inhibitor (TC3) induces G1 arrest, whereas overexpression
of a dominant positive (RhoA QL) shows a cell cycle distribution
similar to the control. Together, these data suggest that TSH
stimulates RhoA in a PKA/HMG-CoA Red-dependent manner and
that this activation may be responsible for TSH down-regulation of
p27kip1, although further study is needed to demonstrate this
hypothesis, currently under investigation.
We show that the specific inhibition of PKA and PI 3-kinase blocks
different TSH effects, indicating their independence, whereas somatostatin inhibits all TSH effects studied. This suggests a mechanism for somatostatin action upstream of PKA and PI 3-kinase and
indicates the inhibitory potential of somatostatin, which is able to
counteract PKA-dependent and -independent proliferative effects. FRTL-5 thyroid cells express the somatostatin receptor SSTR2
(8), and this receptor can be coupled to several downstream effectors
such as adenylyl cyclase or protein-tyrosine phosphatases (55, 56).
Moreover, TSH increases intracellular cAMP levels (28, 43). We thus
tested a possible mechanism of somatostatin inhibition by interference
with TSH-mediated cAMP production. The results clearly show that TSH
increases cAMP intracellular levels by activation of adenylyl cyclase,
whereas somatostatin inhibits cAMP production by inactivation of this
enzyme. The fact that somatostatin inhibits both PKA and PI 3-kinase
pathways after TSH stimulation, by interfering with cAMP production,
reinforces the idea of cAMP-dependent stimulation of both kinases.
Finally, we present a model for the action of TSH and somatostatin in
FRTL-5 thyroid cell proliferation (Fig.
7). In this model, TSH/cAMP can activate
both PKA and PI 3-kinases. Via PKA, TSH thus increases Cdk2 protein
levels and RhoA activation in a HMG-CoA reductase-dependent
manner, whereas via PI 3-kinase, TSH increases cyclin-E protein levels.
Subsequent to these effects, each converges in the phosphorylation of
Rb, leading to progression through the cell cycle. Conversely,
somatostatin inhibits TSH-induced proliferation, decreasing cAMP levels
by inhibition of the adenylyl cyclase activity.
We thank Drs. Isabel Barroso and Juan A. Velasco for the critical reading of this manuscript and Catherine Mark
for linguistic assistance. We are indebted to Dr. Leonard Kohn (NHIDDK,
National Institutes of Health, Bethesda, MD) for the HMG-CoA reductase cDNA, to Dr. Silvio Gutkind (NCI, NIH, Bethesda, MD) for the RhoA QL, RhoA N19, and TC3 expression vectors, and to Dr. Julian Downward (Imperial Cancer Research Foundation, London, UK) for the p110CAAX and
p *
This work was supported by DGICYT Grant PM97-0065, CAM Grant
08.1/0025/97-99, and a grant from Fundación Salud 2000 (Spain).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.
§
Recipient of a fellowship from the Spanish Ministerio de
Educación y Cultura.
2
D. L. Medina and P. Santisteban,
unpublished observation.
The abbreviations used are:
Cdk, cyclin-dependent kinase;
Rb, retinoblastoma;
TSH, thyrotropin;
SSTR2, specific somatostatin receptor type 2;
HMG-CoA, 3-hydroxy-3-methylglutaryl-coenzyme A;
PI, phosphatidylinositol;
GFP, green fluorescent protein;
PKA, cAMP-dependent protein
kinase.
Somatostatin Interferes with Thyrotropin-induced G1-S
Transition Mediated by cAMP-dependent Protein Kinase and
Phosphatidylinositol 3-Kinase
INVOLVEMENT OF RhoA AND CYCLIN E·CYCLIN-DEPENDENT KINASE 2 COMPLEXES*
§,
Instituto de Investigaciones
Biomédicas "Alberto Sols," Consejo Superior de
Investigaciones Científicas, Universidad Autónoma de
Madrid, Arturo Duperier, 4, E-28029 Madrid, Spain and
¶ Departamento de Bioquímica y Biología Molecular,
Facultad de Medicina, Universidad de Alcalá de Henares,
E-28871, Madrid, Spain
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1 (13) and somatostatin (8, 16, 17). TGF-1
interference with TSH action has been studied in FRTL-5 cells
(13); however, the mechanism of interference between somatostatin and
TSH is unknown. It has recently been demonstrated, in another system, that somatostatin interferes with the insulin-mediated induction of
cell cycle proteins by activating p27kip1 (18). This action
takes place through the specific somatostatin receptor type 2 (SSTR2)
expressed in many cell types, including FRTL-5 cells (8).
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]ATP, [
-32P]ATP, and
[-32P]dCTP were from Amersham Pharmacia Biotech. The
IMMUNOcatcher kit was from CytoSignal Research Products.
-32P]dCTP by random priming.
85iSH2-N) that contains a deletion of the regulatory subunit of
PI 3-kinase (32). The role of RhoA was analyzed with a dominant positive RhoA QL (33), dominant negative RhoA N19 (34), or the
botulinum C3 exoenzyme, TC3 (35). In all cases cells were cotransfected
with 1 µg of expression vector encoding green fluorescent protein
(GFP) (36). A group of cells was transfected with the corresponding
empty vector as control. After transfection different hormonal
treatments were used, as detailed in results. Then cells were harvested
and the cell cycle distribution of propidium iodine-stained samples was
performed as described previously (37), using a FACScan flow cytometer
(Becton Dickinson Co.). At least 10,000 events were collected and
analyzed. Data were integrated and plotted with the CellQuest software.
GFP expression was used to normalize transfection efficiency.
-glycerophosphate, 20 µM ATP)
containing 10 µCi of [-32P]ATP (3000 Ci/mmol) and 1 µg of histone H1. Samples were incubated (37 °C, 30 min) and
boiled in protein sample buffer. Proteins were resolved on 12%
SDS-polyacrylamide gel electrophoresis, transferred to nitrocellulose
membrane, and visualized by autoradiography.
80 °C
until use. As described previously (38), membrane extracts were
incubated at 32 °C for 10 min in a 50-µl final volume containing
0.1 mM [32P]ATP (approximately 5 × 106 cpm/assay), 2.0 mM MgCl2, 1.0 mM EDTA, 1.0 mM [3H]cAMP (approximately 15,000 cpm/assay), 0.1% bovine serum albumin, a nucleoside
triphosphate regenerating system composed of 20 mM creatine
phosphate, 26 units/ml creatine kinase, 25 units/ml myokinase, 25 mM Tris-HCl, pH 7.6, 10 µl of membrane extracts, and,
when present, 20 µM GTP, 10 µM TSH, 10 µM somatostatin, 10 µM forskolin plus 0.5%
ethanol. The reactions were terminated, and the [32P]
cAMP formed was assayed by the method of Salomon et al.
(39). The data are the means ± S.D. of three independent experiments.
RESULTS
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ABSTRACT
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EXPERIMENTAL PROCEDURES
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DISCUSSION
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Fig. 1.
Effects of somatostatin and specific
inhibitors of protein kinases on TSH-mediated FRTL-5 cell
proliferation. Cells maintained in basal 3H medium for 3 days were
treated with TSH alone or in combination with somatostatin
(SS), H89, wortmannin (Wort), or PD98059
(PD). A, cell number was monitored at 36 h
after different treatments, and viable cell number is shown.
B, cell cycle distribution represented as G1/S
ratio of FRTL-5 cells. Samples were collected after 36 h for FACS
analysis and plotted with CellQuest software. Values are arbitrary
units considering 3H-maintained FRTL-5 cells as maximal
G1/S ratio. The data are the means ± S.D. of three
independent experiments. All the inhibitors were added 2 h before
TSH treatment on the respective groups. C, effects of PI
3-kinase inhibition. 10 µg of the expression vectors encoding
p85 iSH2-N (dominant negative PI 3-K) or the empty vector
(Control) together with 1 µg of expression vector encoding GFP were
transiently transfected into FRTL-5 cells. Transfected cells were
maintained for 36 h in 3H medium and then treated with TSH for
other 36 h. Cell cycle distribution from propidium iodine-stained
samples was performed using a FACScan flow cytometer. Representative
histograms with the G1/S ratio are shown.
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Fig. 2.
Regulation of G1 cell cycle
proteins in FRTL-5 cells. A, time-dependent
changes in the expression of G1 cyclins and related
molecules in TSH-stimulated FRTL-5 cells. B, effects of TSH,
somatostatin and specific inhibitors of PKA and PI 3-kinase on cell
cycle proteins required to G1/S transition. FRTL-5 cells
were maintained in basal 3H medium and then treated with TSH alone or
in combination with somatostatin (SS), H89, and wortmannin
(Wort) for the indicated times and concentration described
under "Experimental Procedures." Total extracts (50 µg) were
analyzed by immunoblotting with antibodies against cyclin E, Cdk2, and
p27kip1.
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Fig. 3.
Effects of TSH treatment alone or combined
with somatostatin, H89, or wortmannin on the cyclin
E·Cdk2-p27kip1 complexes and retinoblastoma protein
levels. A, 500 µg of total cell lysates were
immunoprecipitated with anti-Cdk2 antibody and immunoblotted against
Cdk2 and cyclin E. Cyclin E·Cdk2 complex activity were assayed for
associated kinase activity using histone H1 as substrate. B,
500 µg of total cell lysates were immunoprecipitated with anti-p27
antibody and immunoblotted against Cdk2 and p27kip1.
C, total cell extract (90 µg) were analyzed by immunoblotting
with antibodies against Rb proteins. Both phosphorylated forms of Rb
are shown. Cell treatment was as described in legend to Fig.
2B. Wb, Western blot.
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Fig. 4.
Somatostatin and H89 inhibit TSH-induction of
HMG-CoA reductase mRNA levels in FRTL-5 cells. Total RNA was
extracted from cells maintained 3 days in 3H medium and then treated
for 12 h with TSH alone or combined with somatostatin
(SS), H89, wortmannin (Wort), or pravastatin
(Prav). A shows a representative Northern blot
hybridized with HMG-CoA reductase probe. For loading control, the 18 S
ribosomal RNA after methylene blue staining is shown. The lower
panels show the effect of pravastatin treatment on cells number
(B) and cell cycle distribution (represented as
G1/S ratio) (C). Samples were collected after
36 h of treatments for FACS analysis and represented with
CellQuest software. Values are arbitrary units considering
3H-maintained FRTL-5 cells as maximal G1/S ratio. The data
are the means ± S.D. of three independent experiments.
View larger version (30K):
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Fig. 5.
TSH activation of RhoA in FRTL-5 cells: role
on cell proliferation. A, immunoblot analysis of RhoA
protein in membrane and cytosolic fraction in FRTL-5 cells stimulated
with TSH (T) alone or combined with somatostatin
(SS), H89, wortmannin (Wort), or pravastatin
(Prav). Quiescent FRTL-5 cells (3H) were incubated with the
different treatments for 36 h and crude membrane- and
cytosolic-containing fractions were prepared. Each sample (50 µg) was
analyzed by immunoblotting with antibodies against RhoA. B,
membrane/cytosol RhoA ratio quantitated after densitometric scanning
and represented as arbitrary units considering TSH-treated cells as
maximum. C, effects of RhoA inhibition on cell cycle
distribution. 10 µg of expression vectors encoding a dominant
positive RhoA QL, dominant negative RhoA N19, or the botulinum C3
exoenzyme, TC3 together with 1 µg of expression vector encoding GFP
were transiently transfected into FRTL-5 cells, Transfected cells were
harvested 2 days later, and cell cycle distribution from propidium
iodine-stained samples was performed, using a FACScan flow cytometer.
Representative histograms are shown.
View larger version (17K):
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Fig. 6.
Mechanism of somatostatin action on
TSH-stimulated FRTL-5 cells. A, effect of somatostatin
(SS) on intracellular cAMP levels. Quiescent FRTL-5 cells
(3H) were treated with TSH alone or in combination with somatostatin
(SS) or octeotride (Oct) for 2 h, and then
intracellular cAMP levels (fmol/well) were quantitated by cAMP
competitive enzyme immunoassay system. B, effect of TSH and
somatostatin on adenylyl cyclase activity. Membrane extracts were
assayed in the presence of TSH (10 µM) or TSH plus
somatostatin at different concentration for adenylyl cyclase assay. The
data are the means ± S.D. of three independent experiments.
DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (11K):
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Fig. 7.
Model of FRTL-5 thyroid cell proliferation by
TSH and somatostatin. TSH activates, via PKA and PI 3-kinase, the
cyclin E·Cdk2 complex formation. PKA (i) induces the activation of
RhoA, in a process that requires HMG-CoA reductase expression and (ii)
down-regulates p27kip1 protein levels. PI 3-kinase
induces cyclin E protein levels. Both pathways converge in the
phosphorylation of Rb leading the progression through cell cycle. On
the other hand, somatostatin inhibits TSH-mediated proliferation much
more up-stream decreasing intracellular cAMP levels by inhibition of
the adenylyl cyclase (AC) activity.
ACKNOWLEDGEMENTS
85iSH2-N expression vectors.
FOOTNOTES
To whom correspondence should be addressed: Instituto de
Investigaciones Biomédicas, CSIC/UAM, Arturo Duperier, 4, 28029 Madrid, Spain. Tel.: 34-91-5854644; Fax: 34-91-5854587; E-mail: psantisteban@iib.uam.es.
ABBREVIATIONS
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RESULTS
DISCUSSION
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