From the
Department of Physiology and Biophysics,
Wright State University School of Medicine, Dayton, Ohio 45435 and the
Instituto de Investigaciones Biomedicas, Consejo
Superior de Investigaciones Cientificas, Facultad Medicina Universidad
Autonoma de Madrid, Arturo Duperier 4, 28029 Madrid, Spain
Received for publication, January 13, 2003 , and in revised form, April 28, 2003.
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ABSTRACT |
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INTRODUCTION |
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In the living cell, ribosomal p70S6K is activated through a complex network
of signaling molecules (15,
16). The generation of
3-phosphoinositide lipid products by PI3K is required for the phosphorylation
of two activating sites in p70S6K: Thr229 and Thr389
(17,
18). Thr229 is
phosphorylated by PDK1 (19,
20) and Thr389 can
be phosphorylated by PDK1 (18)
but also by several other kinases: NEK6/7
(21), mTOR (also known as
FRAP) (12,
22), Akt, and PKC
(23). The formation of a
ternary complex between the regulatory subunit of PI3K (p85), mTOR, and p70S6K
is necessary for the activation of the latter
(24).
The cytokines IL-3, EPO, and IL-2 induce activation of p70S6K (2527), as well as cellular proliferation. Both responses are inhibited with rapamycin, an immunosuppressant drug that complexes with FKBP and binds to mTOR, resulting in the dephosphorylation of p70S6K (3, 28). Growth factor-induced activation of p70S6K and G1 phase cell cycle progression are also blocked by rapamycin or by p70S6K-specific antibodies (25, 26, 29, 30). The structural analog of rapamycin, FK506, competitively binds to FKBP and reverses the inhibition of mTOR by the former (31).
Polymorphonuclear leukocytes (neutrophils) are recruited to sites of inflammation responding to chemoattractants that are secreted by several tissue cells in response to a physical or chemical insult, or by certain bacterial products in the case of a localized infection. The cytokine GM-CSF elicits the two components of cell migration in neutrophils: chemotaxis and chemokinesis.2 GM-CSF has a number of other functions on neutrophils and their bone marrow precursors, that involve the activation of two major signaling cascades: the JAK/STAT and Ras/MAPK pathways (reviewed in Ref. 33). GM-CSF-induced translocation of p42mapk (ERK2) to the cell nucleus and concomitant phosphorylation of the ribosomal kinase p90rsk is central in mitogenic events. Although it has been shown that G-CSF, a human hematopoietic factor related to GM-CSF, activates PI-3K/Akt(PKB) and promotes cell survival (34), little information exists regarding activation of other members of this cell signaling cascade, particularly p70S6K or whether GM-CSF will mediate its physiological effects (notably cell migration) through mTOR-S6K.
We have previously demonstrated that MAPK activation in response to GM-CSF is up-regulated in mature cells such as the neutrophil and plays a role in chemotaxis (35), and that a molecular connection between the MAPK and the p70S6K pathways exists (36). Here we report that p70S6K is present in neutrophils, that GM-CSF causes an increase in phosphorylation of Thr389 and Thr421/Ser424 concomitantly to an increase in its enzymatic activity. We also show for the first time that the mechanism by which GM-CSF activates ribosomal S6K is through a combination of activation of two signaling pathways: mTOR and MAPK.
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EXPERIMENTAL PROCEDURES |
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CellsPeripheral blood neutrophils were isolated based on a protocol described by English and Andersen (37). Between 5055 ml of blood were collected from the antecubital vein of healthy individuals (who signed an Institutional Review Board-approved consent form) using sodium citrate as anticoagulant. Blood was mixed with 15 ml of 6% dextran, allowed to settle, and the plasma and buffy coat were removed and spun down at 800 x g for 5 min. The pellet was resuspended in 35 ml of saline and centrifuged again for 15 min at 10 °C in a Ficoll-Histopaque discontinuous gradient. Neutrophils were recovered and contaminating erythrocytes were lysed by hypotonic shock. Cells were washed and the purified neutrophil pellet was resuspended in Hanks Balanced Salt Solution (HBSS). Our experience has indicated that using this protocol, neutrophil aggregation (i.e. the hallmark for neutrophil activation) does not occur. Viability is usually >98 ± 2% as per trypan blue exclusion. Cells were resuspended at the concentration of 5 x 106 cells/ml in fresh Hanks Balanced Salt Solution (HBSS) or in RPMI at 2 x 106 cells/ml at the time of the experiment, and used within 23 h after isolation.
Immunoprecipitation and Western Blotting AnalysesThe
procedure was based on our previous report
(38) with some modifications,
as follows. Neutrophils were resuspended in RPMI 1640 at 3 x
106 cells/ml density and were pretreated with rapamycin, FK506, or
MEKi where appropriate and then stimulated with GM-CSF at 37 °C. Aliquots
(1 ml) were taken, spun down (14,000 x g, 15 s) and pellets
were resuspended in 0.2 ml of boiling SDS solution (1% SDS in 10 mM
Tris-HCl, pH 7.4). Samples were boiled in a heat block for 10 min with
frequent vortexing to achieved complete dissolution, taken to an ice bucket
and mixed with 0.3 ml cold ddH2O and 0.4 ml of cold, Triton
X-100-based, lysis buffer (12 mM Tris-HCl, pH 7.2, 0.75
mM NaCl, 100 µM sodium orthovanadate, 10
mM phenylmethylsulfonyl fluoride, 0.2 mM
-glycerophosphate, 5 µg/ml each of aprotinin, pepstatin A, and
leupeptin, and 0.12% Triton X-100). The resulting 1 ml of total cell lysates
were spun down (14,000 x g, 1 min, 4 °C) to remove any
insoluble material and then used for immunoprecipitation. For this, the
primary antibody (anti-p70S6K) was previously mixed at a final concentration
of 2 µg/ml with anti-rabbit (IgG, whole molecule) antibody conjugated to
agarose beads in lysis buffer for 4 h at 4 °C. The beads were then
thoroughly washed and mixed with total cell lysates prepared as indicated
above at a ratio agarose beads/cell lysates 1:8 (v/v). After a 2-h incubation
period at 4 °C, immune complexes were recovered by centrifugation (7,000
x g, 1 min, 4 °C). Pellets were washed twice with lysis
buffer, twice with buffer A (100 mM Tris-HCl, pH 7.4, 400
mM LiCl) and twice with buffer B (10 mM Tris-HCl, pH
7.4, 100 mM NaCl, 1 mM EDTA). Immune complex beads were
resuspended in a final volume of 60 µl with lysis buffer and mixed with
2x-SDS sample buffer (1:1 v/v) for subsequent protein gel
electrophoresis/immunoblotting. Resulting gels were transferred onto
polyvinylidene difluoride membranes and used for immunoblotting. In several
experiments, parallel blots were probed with the same antibody used for
immunoprecipitation, to confirm that protein loading was similar (kept at
<5% by measuring protein in samples by Bradford assay before loading) and
that the small, unavoidable, differences in protein per lane can not account
for differences in phosphorylation seen with the anti-phosphoantibodies.
Immunocomplex p70S6 Kinase AssayRibosomal p70S6K enzymatic
activity was quantified by using an immunocomplex kinase assay as reported
previously (35,
36,
38) tailored to measure this
particular kinase activity in human neutrophils. Neutrophils were resuspended
in RPMI 1640 at 3 x 106 cells/ml density and were pretreated
with rapamycin, FK506, or MEKi where appropriate and then stimulated with
GM-CSF at 37 °C. Cells were spun down (14,000 x g, 15 s)
and pellets were resuspended in 0.3 ml of ice-cold, TRIS-based, lysis buffer
(see above for composition) and incubated on ice for 15 min with occasional
vortexing. Lysates were obtained after centrifugation (7,000 x
g, 1 min, 4 °C) in supernatants were mixed with the antibody
conjugated to agarose beads as indicated above. Immune complex beads were
resuspended in a final volume of 40 µl with of ice-cold lysis buffer
(diluted 1:10) and used in an in vitro kinase assay. For this, the
phosphoacceptor peptide substrate for this assay was 75 µM of
the S6 kinase substrate peptide KKRNRTLTK in freshly prepared kinase buffer
(13.4 mM HEPES, pH 7.3, 25 mM MgCl2, 30
µM Na2VO3, 5 mM
p-nitrophenyl phosphate, 2 mM EGTA, 2 µM
cAMP-dependent kinase inhibitor TTYADFIASGRTGRRNAIHD, 0.420 µCi
[-32P]ATP (7 nM), and 68 µM
unlabeled ATP). 1 µg of cAMP-dependent kinase inhibitor inhibits
2,0006,000 phosphorylating units of PKA (equivalent to the transference
of 26 nmol of phosphate from ATP). To initiate the phosphotransferase
reaction, aliquots (20 µl) of kinase buffer containing the appropriate
substrates were mixed 1:3 (v/v) with the cell lysates or immunocomplex beads.
The reaction was carried out at 37 °C for 20 min in a rotator and
terminated by blotting 40 µl of the reaction mixture onto P81 ion exchange
chromatography cellulose phosphate papers. Filter squares were washed, dried,
and counted for radioactivity. Controls were run in parallel with no S6 kinase
substrate peptide. Counts were subtracted from samples. In some experiments,
ribosomes were used as the natural p70S6K substrate following the in
vitro kinase assay just indicated. Protein S6 is part of a
multiprotein-rRNA complex that is multiphosphorylated on Ser residues in
vitro in response to mitogenic stimulation. 40 S ribosomal subunits were
prepared from Xenopus laevis at the concentration of 0.10.25
mg/ml following the procedure described in Ref.
11.
Alkaline Phosphatase TreatmentSDS-boiled samples as indicated in the immunoprecipitation and Western blotting analyses section above were diluted with 0.3 ml of cold H2O and 0.4 ml cold, Triton X-100-based, lysis buffer. The alkaline phosphatase enzyme (calf intestine-purified) was added in a 160 µl of total volume of freshly prepared, cold, alkaline phosphatase buffer (25 mM Tris-HCl, pH 7.6, 1mM MgCl2, and 0.1 mM ZnCl2). To initiate the phosphate removal reaction, 48 µl of 3 M Tris-base, pH 12.5 were added to each sample to achieve a favorable reaction pH of 10.0 ± 0.5. Samples were lightly vortexed and incubated at 37 °C for 45 min with slight agitation. The reaction was stopped by placing the samples on an ice bucket and adding to each reaction tube a small volume of 10 M Tris-HCl, pH 3.0 in order to bring the reaction pH to 7.0. Samples were used immediately for immunoprecipitation using anti-p70S6K antibodies, as indicated above.
F-actin Measurement by Flow CytometryNeutrophils were stained with phalloidin-FITC as described (39) with some modifications. Briefly, F-actin polymerization was initiated in vivo by the addition of GM-CSF to a neutrophil cell suspension (5 x 106 cells/ml) for 5 min at 37 °C. After this, 0.2-ml aliquots were taken and mixed with 1 ml of pre-chilled fixing solution (two parts of double-concentrated phosphate buffer, pH 7.4, one part of 20% formaldehyde and one part of 75% glycerol in water). Samples were stored at 80 °C until ready for flow cytometry. At that time, samples were thawed and spun down for 5 min at 600 x g in a refrigerated Eppendorf microcentrifuge. Pellets were resuspended in freshly prepared F-actin staining solution (35 µlofa3.3 mg/ml methanol FITC-phalloidin stock plus 315 µl of H2O, and stained in the dark for 30 min at room temperature. Samples were centrifuged as above, and pellets were resuspended in 1 ml of FACS FLOW. They were then analyzed by flow cytometry on a FACSCAN Becton & Dickinson flow cytometer at 488 nm excitation wavelength. Data was analyzed using Cell Quest software and expressed as fluorescence intensity.
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RESULTS |
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After protein, activity and kinetic measurements, we next investigated whether GM-CSF was able to induce the phosphorylation of p70S6K in human neutrophils. As seen in Fig. 3A, GM-CSF induces a rapid (3 min) phosphorylation of p70S6K on Thr389, which is one of the residues critical for S6K activation. The migration of the phosphorylated band in SDS gels very well coincides with that of the 3T3 fibroblast controls. Also, GM-CSF induces phosphorylation of p70S6K on two other residues, Thr421/Ser424 (Fig. 3B), that are also key for conferring enzyme activity. The effect is dose-dependent, clearly noticeable with GM-CSF concentration as low as 0.5 nM.
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Fig. 4 shows that the increase in both phosphorylation and enzyme activity elicited by GM-CSF are time-dependent. A maximum phosphorylation at 3 min is seen for phospho-Thr421/Ser424 (Fig. 4A) as well as for phospho-Thr389 (Fig. 4B). Phosphorylation of Thr389 is seen as an increase in density of the immunoprecipitated p70 band. The Thr421/Ser424 dual phosphorylation is seen at 35 min post GM-CSF, and is demonstrated by both a robust increase in density of the immunoprecipitated p70 band and by an upward mobility shift (Fig. 4A). The figure also shows results of immunoprecipitation with anti-p70S6K antibody and immunoblotting with the same antibody to demonstrate equal loading (Fig. 4C). In vitro kinase activity experiments also reveal a time-dependent increase due to GM-CSF (Fig. 4D). Maximal activity is reached at 5 min and declines slightly thereafter, and as such, the biphasic pattern of phosphorylation seen in Fig. 4, A and B correlated with enzymatic activity.
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Thus, the results presented in Figs. 1, 2, 3, 4 demonstrate that p70S6K is expressed in human neutrophils, that GM-CSF increased its enzymatic activity in a time and dose-dependent fashion, changes the Vmax for its peptide substrate, and that this cytokine induces robust phosphorylation in 3 key residues: Thr389, Thr421, and Ser424.
mTOR Is Involved in GM-CSF-activated p70S6K in NeutrophilsThe next series of experiments were aimed at investigating what the mechanism that accounts for the observed increases in both phosphorylation and activity, was. Our first approach was the use of the immunosuppressant drug rapamycin, a well known inhibitor of mTOR, one of the several upstream regulators of p70S6K (17). In neutrophils, rapamycin inhibited GM-CSF-stimulated p70S6K Thr389 phosphorylation in a concentration-dependent manner (Fig. 5A). The intensity of phospho-Thr389 signal all but disappears at 10 nM.
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The effect of rapamycin on the dual phosphorylation Thr421/Ser424 was also very profound, but manifested itself differently and warranted close examination. Fig. 6A shows that rapamycin causes a dramatic downward mobility shift in the phospho-Thr421/Ser424 band observed in the presence of GM-CSF. In this study, for the sake of clarification, we have labeled the lower band in GM-CSF + rapamycin as a and the upper band in GM-CSF alone as b. A shift from the upper b to lower a band observed with rapamycin treatment, is consistent with p70S6K dephosphorylation, as a less phosphorylated species runs faster in SDS-PAGE. Also shown in Fig. 6A (to the right) is a representative Western blot of fibroblast lysates to provide yet one more relative mobility comparison. The upper b band in GM-CSF-treated neutrophils has a Mr similar to that of serum-treated fibroblasts. Fig. 6A also shows that, in contrast to what was observed with phospho-Thr389 where the intensity signal disappeared with rapamycin + GM-CSF (Fig. 5A), a positive signal is still present to anti-phospho-Thr421/Ser424 antibodies, indicating that phosphorylation of Thr421/Ser424 was not completely affected by rapamycin.
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To ascertain if the signal to Thr421/Ser424 antibodies still remained simply because there was not enough rapamycin to inhibit it, we analyzed the status of this dual phosphorylation in response to GM-CSF with a range of rapamycin concentrations. Fig. 6B confirms that concentrations of rapamycin as low as 0.5 nM had already increased the mobility of p70S6K, and this effect remains present at all concentrations tested. A weakened signal to the antibody was noticeable at higher concentrations (with similar protein loading in the SDS gel, as shown in Fig. 6B), but the signal was not completely eliminated, even at a concentration of 50 nM. Thus, rapamycin causes a potent change in electrophoretic mobility of p70S6K but there was still a rapamycin-resistant component of phosphorylation.
A partial inhibition of p70S6K by rapamycin is not entirely unlikely. Although it was originally described as a blocker of agonist-stimulated p70S6K activity in several cell lines (11, 29, 31), rapamycin may have differential effects on other systems. A dissociation between TOR kinase activity and rapamycin action has been already described (40, 41). Additionally, a recent example of discrepancy between rapamycin inhibition and p70S6K activity could be found in (42). At any rate, an inhibitor of a S6K cellular pool should be enough to explain the profound physiological effect of rapamycin on chemotaxis.3
We needed to prove that the mobility downshift from b to a is indeed due to the disappearance of phosphorylated residues. For this, we performed the following control experiment: we treated GM-CSF-stimulated neutrophil lysates with increasing concentrations of alkaline phosphatase in vitro. Then, we used the lysates to perform p70S6K immunoprecipitation and immunoblotting in a fashion similar to that followed in the previous experiments. Fig. 6C shows that as the phosphatase concentration increases for 1080 units/ml, the phosphorylated p70S6K band shifts from the original b position (GM-CSF-stimulated cells, no alkaline phosphatase added) to the lower a position. This position is equivalent to the rapamycin-treated GM-CSF-stimulated cells (Fig. 6, A and B). We therefore concluded that a shift of the nature observed in pp70S6K with rapamycin is, in effect, due to the loss of phosphate. Further, the maximum dose of alkaline phosphatase used in this experiment (80 units/ml), provides, in addition to the band downshift, a weakened signal to the antibodies (Fig. 6C), most likely due to the fact that alkaline phosphatase can dephosphorylate all the residues of a target substrate, regardless of the amino acid moiety.
The fact that rapamycin has a profound effect on changing the phosphorylation of p70S6K induced by GM-CSF points strongly to a participation of mTOR in the mechanism of signaling action. To further confirm this, we made use of FK506, another macrolide immunosuppressant structurally related to rapamycin. Like rapamycin, FK506 is a ligand of the immunophilin FK506-binding protein-12 (FKBP12) but exerts its action by mechanisms different from rapamycin (31). The mechanism is mTOR-related because: (a) unlike rapamycin, FK506 did not negatively affect the status of phosphorylation of p70S6K nor did it produce any downshift (Fig. 7A), and (b) the inhibition of GM-CSF-induced p70S6K phosphorylation caused by rapamycin was rescued by pretreatment of cells with FK506 (Fig. 7B). The less phosphorylated a band moves up to restore the mobility of the hyperphosphorylated b band at 1 µM FK506. This high concentration is similar to that used by other authors in this type of experiments (17, 31). Since FK506 binds FKBP12, which is also the soluble receptor for rapamycin, a competition between the two ligands ensues. It has been established earlier that at high enough concentrations, FK506 reverts the effects induced by rapamycin (17, 31, 4345).
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MAPK Is the Other Necessary Component Involved in GM-CSF-activated p70S6K in NeutrophilsSince rapamycin could not completely dephosphorylate p70S6K, we were interested in knowing at what extent the in vitro enzymatic activity of p70S6K would be affected by rapamycin. As presented in Fig. 8, pretreatment of cells with rapamycin prior to stimulating with GM-CSF caused an inhibition of enzymatic activity with an IC50 of 0.2 nM. However, this inhibition was never complete but, instead, reached only 4050% of the GM-CSF-induced maximal level. Higher doses of rapamycin, even as high as 50 nM, did not cause further inhibition. These results indicate that neutrophil p70S6K activity, similarly to phosphorylation, has a rapamycin-resistant component. To investigate what the regulation of this component might be, we based our next experiments on the previous observation from our laboratory that there is a cross-talk between the MAPK and the p70S6K pathway (36), as well as on other authors work (46) who have indicated that a cluster of Ser/Thr-Pro sites in the p70S6K C-terminal tail can be phosphorylated in vitro by proline-directed kinases, such as ERK1/2 or cdc2.
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We were wondering if the MEK/MAPK pathway could account for the rapamycin-resistant component of S6K activation. As presented in Fig. 9A, the MEK inhibitor PD-98059 (MEKi) also caused a partial inhibition of p70S6K activity. However, when cells were treated with a combination of PD-98059 and rapamycin prior to stimulation with GM-CSF, the loss of activity was complete, with levels returning to basal levels (note that bars on the far right and the far left are about equal). As an additional proof of the cooperative inhibitory effect of the combination rapamycin + MEKi, we measured F-actin polymerization by flow cytometry. Results in Table I show that even though the effects of rapamycin and MEKi on inhibiting actin were mild, when they were combined the levels of actin returned to basal, pre-stimulatory levels.
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Next, in order to show that not just any combination of rapamycin with another drug would further the inhibition of p70S6K, we tested a combination of rapamycin and FK506. As seen in Fig. 9B, this combination nor only did not improve the inhibitory effect of rapamycin but, rather, enhanced it (in vitro kinase activity of GM-CSF-treated neutrophils is not inhibited with FK506, not shown).
Finally, Fig. 10 shows that at the level of phosphorylation, a combination of rapamycin and MEKi produced a downshift in the phospho band and diminished signal to the anti-phospho antibodies. Fig. 10A shows results with phospho-Thr421/Ser424, and Fig. 10B with phospho-Thr389 very similar to that observed with the in vitro treatment with alkaline phosphatase of Fig. 6C, that produced a large removal of phosphate. It should be noted that the dephosphorylation is complete when the antibodies used were against Thr389, which lends strength to the point of the full effect of the combination rapamycin plus MEKi.
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DISCUSSION |
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As far as we can discern, this is the first full report showing p70S6K in neutrophils and, for that matter, in a hematopoietic primary cell, its kinetic data, and its mechanism of regulation with GM-CSF. The enzyme velocity value for neutrophils (7.2 to 20.5 pmol/min/mg protein) of Fig. 2D is well in agreement with other authors who have reported kinetic data in the low picomolar range for hepatoma cells, PMA-stimulated, transfected COS-7, liver extracts of cycloheximide-stimulated rats and ion-exchange purified cell extracts, Swiss 3T3 cells stimulated with EGF and insulin and Xenopus oocytes (11, 4751). Only the enzyme purified to near homogeneity displays activity in the high nanomolar range (47, 50, 51). There are two precedents that have briefly touched upon the presence of p70S6K in either leukemic cells or mature phagocytes. In a study of the role of STAT3 in GM-CSF-induced enhancement of neutrophilic differentiation of Me2SO-treated HL-60 cells, Yamaguchi et al. (52) found that p70S6K could be activated. p70S6K is also activated upon PECAM-1/CD31 cross-linking, based on the appearance of serine phosphorylation in S6K immunoprecipitates (53). However, since p70S6K is not directly involved in integrin function (as per rapamycin evidence) the authors emphasize the upstream link, PI3K, as a common pathway of integrin and adhesiveness regulation in leukocytes.
To investigate p70S6K in neutrophils, we have concentrated in a parallel
study of enzyme activity and analysis of the phosphorylation status of three
key residues (Thr389 and Thr421/Ser424),
working with specific anti-p70S6K immunoprecipitates. Immunoprecipitation with
specific anti-p70S6K antibodies and immunocomplex assays with an also specific
p70S6K peptide substrate (KKRNRTLTK, that bears the consensus site
phosphorylation), accurately describes this particular kinase. Phosphorylation
of 40 S ribosomal subunits (a natural substrate bearing the S6 protein) as
presented in Fig. 1B
also serves to fully confirm the p70S6K activity in neutrophils. To study the
mechanism of p70S6K regulation elicited by GM-CSF in neutrophils, we have
employed several strategies, the first one being the use of rapamycin. We have
observed that this immunosuppresant does inhibit Thr389
phosphorylation as previously reported by other authors
(44). These authors have
established that a mutation of Thr389 to alanine (T389A) makes
p70S6K rapamicyn resistant and "kinase dead," i.e. the
enzyme becomes unable to be activated by cytokines or growth factors. However,
an endogenous, native, kinase like the one described here in neutrophils can
be partially activated by GM-CSF even in the presence of rapamycin, since
other residues will be available for phosphorylation in the intact cells.
Furthermore, the same authors mutated Thr389 to an acidic residue
and the T389E mutant in quiescent cells had a high basal activity and was able
to be activated by serum, but only to a 50% level of the wild-type construct
(44). Data in
Fig. 8 (present paper) seem to
be in agreement with results on the T389E mutant, but not with T389A. Also
regarding rapamycin in the present study, but this time as we investigated
residues other than Thr389, we uncovered for the first time the
unexpected effect of rapamycin on mobility shifts on
Thr421/Ser424. The effect was very dramatic as it
represented a change of 34 kDa in the gels
(Fig. 6, A and
B). This correlated well with a loss of phosphate as
presented in control experiments with alkaline phosphatase
(Fig. 6C). The origin
of this phosphate could not be established at this time but since the
anti-phospho-Thr421/Ser424 antibodies still gave a
positive signal, it could not be associated to
Thr421/Ser424 residues but to any of the several others
that have been reported to be phosphorylated upon growth factor or cytokine
stimulation (3,
12,
13,
14).
Another strategy to study the mechanism of p70S6K activation, has been the use of FK506. The rapamycin-related, immunophilin, FK506 does not inhibit mTOR or p70S6K (rather, it acts through PP2A). As such, it is normally used in these type of studies as a valuable test to ascertain if an agonist effect specifically utilizes mTOR/p70S6K as a cell signaling mechanism. Our data show that FK506 does not inhibit, indicating that GM-CSF does work through mTOR/p70S6K. But the use of FK506 had an additional benefit. Since this drug binds to the FKBP12, which happens to be also the soluble receptor for rapamycin, a competition between the ligands ensue. At high enough concentrations, FK506 reverts the effects of rapamycin. Even though this has been reported earlier (17, 31) the present article is the first of its kind to have uncovered this in neutrophils, and further proves that point. Also here, the novel finding of rapamycin inhibiting only 4050% of the enzymatic activity: the remainder is inhibited when the MEK/MAPK pathway is altered.
Since the combination of rapamycin and MEKi is necessary for full inhibition of p70S6K activity and phosphorylation, we can reasonably conclude that the two known kinases targeted by these inhibitors are needed to activate p70S6K in the first place. A model for the activation of p70S6K in human neutrophils is presented in Fig. 11. The data in this study are consistent with GM-CSF dually stimulating the activity of a Thr421/Ser424 kinase and a Thr389 kinase, resulting in full activation of neutrophil ribosomal p70S6K. Although the identity of these two kinases has not been addressed in this study, the data strongly point to a MEK-related or -activated Thr421/Ser424 kinase (possibly MAPK) and a rapamycin-sensitive, mTOR-related or -activated Thr389 kinase (possibly TOR itself). This study also indicates that both pathways must work simultaneously in order to achieve full activation of p70S6K by GM-CSF.
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The effects of rapamycin could be mediated by either blocking the activation of a Thr389 kinase or by activating a Thr389 phosphatase, or by a combination of both. Also, other residues that we have not explored in this study might be implicated. Even though it is well known (3, 4, 12, 13, 1721) that at least 12 Ser/Thr residues can be phosphorylated upon cell stimulation, there would be unpractical to examine each one of them. Importantly, Ser371 is a critical residue (13) that could explain that phosphorylation of Thr389 or Thr421/Ser424 is necessary but not sufficient to achieve full activation. Also, more experiments are needed to verify if MAPK signaling indeed only regulates S6 kinase via its C-terminal site. All and all the further unveiling of the molecular mechanism of GM-CSF-induced p70S6K activation in neutrophils deserves future investigation. A confirmation of the results presented here could come from the study of mammalian cell transfection with DNA mutants (which will be technically challenging in the neutrophil, a short-lived cell that can not be cultured) or with protein mutants. To this respect, Gardiner et al. (54) have shown that protein delivery (or transduction) to neutrophils can be successfully accomplished, as demonstrated with Rac. However tantalizing these kind of reconstitution studies may be, the lack of crucial molecular reagents (the full-length, wild-type p70S6K protein, and dominant negative or constitutively active mutants) prevent further studies on p70S6K at this time.
At any event, results shown here with neutrophils clearly indicate for the first time that we should look for effects of p70S6K other than those described for the ribosomal machinery, since the translational capabilities (the role classically assigned to p70S6K as an activator of ribosomal protein S6) of those cells are minimal. To this respect, other authors have proposed that p70S6K is involved in IL-8 production in mononuclear cells from rheumatoid arthritis synovial tissue (55). In macrophages, p70S6K has been linked with FKBP12-rapamycin-associated phosphorylation of iNOS and LPS-induced NO production and TNF-a synthesis (56, 57). A role of p70S6K in survival of cytokine-stimulated T cells or apoptosis has been ruled out (32). As an extension of the present study, we are currently exploring a possible role for p70S6K in one key physiological response of neutrophil during phagocytosis, cell migration, that is in agreement with cytoskeletal polymerization data presented in Table I.
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FOOTNOTES |
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¶ To whom correspondence should be addressed: Dept. of Physiology & Biophysics, Wright State University School of Medicine, 3640 Colonel Glenn Highway, Dayton, OH 45435. E-mail: julian.cambronero{at}wright.edu.
1 The abbreviations used are: p70S6K, ribosomal p70-S6 kinase; GM-CSF,
granulocyte macrophage colony-stimulating factor; G-CSF, granulocyte
colony-stimulating factor; EPO, erythropoietin; IL-8, interleukin-8; PI3K,
phosphatidylinositol 3-kinase; PDK1, 3-phosphoinositide-dependent protein
kinase; MAPK, mitogen-activated protein kinase; MEK, MAPK kinase; MEKi, MEK
inhibitor PD-98059; mTOR, mammalian target of rapamycin; FKBP, FK506-binding
protein; FRAP, FKBP12-rapamycin-associated protein; PP2B, protein phosphatase
2B.
2 J. Gomez Cambronero, J. Horn, M. A. Baumann, and C. C. Paul, submitted
manuscript.
3 J. Gomez-Cambronero, unpublished observations.
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ACKNOWLEDGMENTS |
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REFERENCES |
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