(Received for publication, October 31, 1996)
From the Department of Neurology, Division of Neurochemistry and Neurobiology, University of Iowa College of Medicine and Veterans Affairs Medical Center, Iowa City, Iowa 52242
We observed previously that glia maturation factor (GMF), a 17-kDa brain protein, is rapidly phosphorylated in astrocytes following stimulation by phorbol ester, and that protein kinase A (PKA)-phosphorylated GMF is a potent inhibitor of extracellular signal-regulated kinase (ERK) and enhancer of p38; both are subfamilies of mitogen-activated protein (MAP) kinase, suggesting GMF as a bifunctional regulator of the MAP kinase cascades. In the current report, we present evidence that PKA-phosphorylated GMF also promotes (11-fold) the catalytic activity of PKA itself, resulting in a positive feedback loop. Furthermore, GMF phosphorylated by protein kinase C (PKC), but not by casein kinase II or p90 ribosomal S6 kinase, also activates PKA (7-fold). It appears that the mutual augmentation of GMF and PKA, and the stimulating effect of PKC, both serve to maximize the influence of PKA on the regulation of MAP kinase cascades by GMF. Using synthetic peptide fragments containing putative phosphorylation sites of GMF, we demonstrate that PKA is capable of phosphorylating threonine 26 and serine 82, whereas PKC, p90 ribosomal S6 kinase, and casein kinase II, can phosphorylate serine 71, threonine 26, and serine 52, respectively. The generation of various phospho-isoforms of GMF may explain its modulation of signal transduction at multiple locations.
Glia maturation factor (GMF)1 is a 17-kDa brain protein that was purified (1), sequenced (2), and cloned (3) in our laboratory. The highly conserved amino acid sequence of GMF contains several consensus phosphorylation sites, including sites for protein kinase A (PKA), protein kinase C (PKC), casein kinase II (CKII), and p90 ribosomal S6 kinase (RSK). In fact, we demonstrated previously that recombinant GMF can be phosphorylated by PKA, PKC, CKII, and RSK, whereas endogenous GMF is rapidly phosphorylated at both serine and threonine residues following stimulation of astrocytes by phorbol ester (4). Thus, it is possible that various phosphorylated isoforms of GMF may be generated inside the cell by kinases differentially stimulated by external stimuli. Although no isoform of GMF, phosphorylated or nonphosphorylated, possesses kinase or phosphatase activity (4, 5), we have shown recently that PKA-phosphorylated GMF is a potent inhibitor of ERK (5) and also an enhancer of p38 (6); both are subfamilies of MAP kinase, suggesting that GMF is a bifunctional regulator of the MAP kinase cascades. To find out any additional locations where GMF can regulate, we have tested the effect of GMF and GMF-P on PKA. In the present communication, we demonstrate the stimulatory effect of two phosphorylated isoforms of GMF, PKA- and PKC-phosphorylated GMF, on the catalytic activity of PKA.
PKA (catalytic subunit purified from bovine
heart) was obtained from Promega Corp. PKC (from rat brain) was a
product of Calbiochem. RSK (RSK-2), from rabbit skeletal muscle, was
obtained from Upstate Biotech. Recombinant human CKII was from
Boehringer Mannheim. PMA and kemptide (PKA substrate LRRASLG) were from
Sigma. Monoclonal anti-PKA (catalytic subunit)
antibody and polyclonal anti-Pan PKC antibody were from Transduction
Labs and Upstate Biotech, respectively. GMF was a recombinant human
protein (3) from Escherichia coli (over 98% pure). CT-11
was a mouse monoclonal antibody (IgG1) against a synthetic
peptide corresponding to the C-terminal 11 amino acid residues of human
GMF and was affinity purified with protein A. [-32P]ATP (3000 Ci/mmol) was purchased from DuPont
NEN. GMF peptides for phosphorylation experiments were custom
synthesized by Genemed Biotech (South San Francisco, CA), except
peptides I and IV, which were gifts of R. A. Copelend of DuPont Merck
Pharmaceutical.
Recombinant GMF was phosphorylated by various protein kinases as follows. GMF (2 µg) was incubated overnight at room temperature in a 40-µl reaction mixture containing the following: 25 mM Tris-HCl, pH 7.5, 25 mM MgCl2, 3.75 mM EGTA, 0.15 mM sodium vanadate, 1 mM dithiothreitol, 10 µM okadaic acid, 0.02% sodium azide, and 10 mM ATP (nonradioactive) in the presence of either PKA (80 units), PKC (100 ng), RSK (2 µg), or CKII (0.5 milliunits). (The concentrations of the kinases were adjusted to obtain comparable degrees of GMF phosphorylation, as determined by previous autoradiography.) The reaction mixture for PKC also contained 0.6 mM CaCl2, 40 µg/ml phosphatidyl serine, 0.8 µg/ml dioctanoylglycerol, and no EGTA. The reaction mixture for RSK also contained 4 µM PKC inhibitor peptide (RFARKGALRQKNV), 0.4 µM PKA inhibitor peptide (TYADFIASGRTGRRNAI) and 4 µM calmidazolium. In control tubes (mock GMF-P), the reaction was carried out in the absence of GMF. At the end of the overnight incubation, GMF was separated from ATP and the kinases by immunoprecipitation using the monoclonal anti-GMF antibody (CT-11). For immunoprecipitation, each reaction mixture was diluted with 1 ml of buffer A (see below) containing 1% Triton X-100. The incubation with CT-11 (10 µg/ml) was for 1 h at room temperature, followed by one additional hour of incubation with 20 µl of a 50% suspension of protein G-agarose. The immune complex containing GMF and GMF-P was collected and washed three times by brief centrifugations before being used in the PKA assay system. An aliquot of the immune complex was analyzed on SDS-polyacrylamide gel, stained with Coomassie Blue, and scanned with a Hewlett Packard ScanJet II CX/T to calculate the percentage of GMF phosphorylated by various kinases and the percentage of GMF recovered by immunoprecipitation, as described earlier (5).
PKA/Kemptide AssayAssay for PKA activity was carried out
in a 40-µl reaction volume containing 100 µM kemptide
substrate, 0.1 unit PKA (Promega), various amounts of GMF or GMF-P
(both as immune complex), in 25 mM Tris-HCl, pH 7.5, 25 mM MgCl2, and 125 µM
[-32P]ATP (2000 cpm/pmol), and incubated at 30 °C
for 10 min. At the end of incubation, the reaction mixture was diluted
to 100 µl with the above buffer and centrifuged once in Microcon-10
(Amicon) to separate the peptide substrate from the enzyme and GMF. A
25-µl aliquot of the filterate was spotted on P81 phosphocellulose
paper (Whatman), washed with two changes of 0.75% phosphoric acid for 1 h, air dried, and counted in a scintillation counter. For
calculation, values from "mock GMF-P" were subtracted from
corresponding values obtained from GMF-P; likewise, values from mock
GMF were subtracted from those obtained from GMF. GMF samples not
intended for phosphorylation went through the same preincubation (in
the absence of kinase) and immunoprecipitation steps as for GMF-P
(5).
The analysis of
kinases present in C6 cell extract capable of phosphorylating GMF was
carried out by an "in-gel" kinase assay as described by others (7,
8). For this purpose, near-confluent C6 cells were harvested into
buffer A (1 ml/T-75 flask) consisting of 50 mM Tris-HCl, pH
7.5, 100 mM NaCl, 50 mM NaF, 0.1 mM
sodium vanadate, 10 µM okadaic acid, 1 mM
phenylmethylsulfonyl fluoride, and 10 µg/ml each of the following
proteinase inhibitors: aprotinin, leupeptin, chymostatin, pepstatin A,
and antipain. The cells were sonicated in the cold at 50 W for two
bursts of 30 s each and then centrifuged at 4 °C at
100,000 × g for 1 h. The supernatant thus
obtained was electrophoresed on SDS-polyacrylamide gels (9) using a
12% separation gel containing recombinant GMF (0.1 mg/ml) embedded in
the gel matrix. After electrophoresis, the gels were washed three times
(20 min each) with 20% isopropanol in 50 mM Tris-HCl, pH
8, to remove the SDS. The in situ denaturation-renaturation of protein kinases was carried out by first incubating the gels in a
solution containing 6 M guanidine-HCl in 50 mM
Tris-HCl, pH 8, and 5 mM dithiothreitol for 1 h at
room temperature, and then incubating overnight at 4 °C in 50 mM Tris-HCl, pH 8, 5 mM dithiothreitol, and
0.04% Tween 20. The kinase assay was performed by incubating the gels
in a kinase assay buffer (40 mM HEPES, pH 8, 2 mM dithiothreitol, 0.1 mM EGTA, and 5 mM magnesium acetate) containing 50 µM ATP
and 50 µCi [-32P]ATP for 1 h at room
temperature. The gels were washed extensively with several changes of
5% (w/v) trichloroacetic acid and 1% (w/v) sodium pyrophosphate. The
gels were dried and exposed to XAR film (Eastman Kodak Co.) with
intensifying screen at
70 °C for 3 days. The kinase activity was
revealed by incorporation of 32P into matrix-bound GMF, and
the size of the individual kinase was estimated from the known
prestained protein markers (Bio-Rad) run in the same gel. A piece of
control gel where GMF was omitted was processed in the above manner to
detect autophosphorylation of the kinase bands.
A number of peptide
fragments were synthesized according to the sequence of human GMF, each
containing a single serine or threonine residue corresponding to the
putative phosphorylation site of either PKA, PKC, RSK, or CKII.
Phosphorylation studies were carried out in a reaction mixture of 40 µl containing 200 µM of a synthetic peptide, 125 µM [-32P]ATP (2000 cpm/pmol), and an
appropriate amount of protein kinase as described above ("Preparation
of Phosphorylated GMF"). The reaction was carried out at 30 °C for
10 min. At the end of incubation, equal aliquots from the reaction
mixtures were spotted on P81 phosphocellulose paper, washed twice,
dried, and counted as described above. The values were corrected for
autophosphorylation of the kinase enzymes in the absence of peptide
substrate.
In the present study, we surveyed the effects of various
phosphorylated isoforms of GMF, obtained by the action of PKA, PKC, RSK, and CKII, on the activity of the catalytic subunit of
cAMP-dependent protein kinase (PKA). Recombinant GMF was
first reacted with each of the kinases to obtain GMF-P, which was then
purified by precipitation with an anti-GMF monoclonal antibody. The
immune complex in various amounts was then added to a test system
consisting of PKA, [-32P]ATP, and the PKA- specific
substrate kemptide. Results in Fig. 1 show a significant
increase in kemptide phosphorylation by PKA in the presence of PKA- and
PKC-phosphorylated GMF, but not GMF phosphorylated by RSK or CKII. Fig.
2 compares the dose-response curves of PKA- and
PKC-phosphorylated forms of GMF, along with that of unmodified GMF.
PKA-phosphorylated GMF showed a maximum stimulation of 11-fold over the
baseline value (in the absence of any GMF); the corresponding value for
PKC-phosphorylated GMF was 7-fold. On the other hand, nonphosphorylated
GMF showed only a minor stimulatory effect, with a maximum stimulation
of 1.6-fold. At 20 nM, the increase in activity over
nonphosphorylated GMF was 6.7-fold for PKA-phosphorylated GMF and
4.1-fold for PKC-phosphorylated GMF. The half-maximal activity
(EC50) for both phosphorylated forms of GMF was about 3 nM.
In the next experiment, we tested the effects of multiple
phosphorylation on the function of GMF. GMF was phosphorylated by a
combination of PKA and one or more other kinases and subsequently tested in the PKA/kemptide assay. As shown in Fig. 3,
neither RSK nor CKII augmented or inhibited the action of
PKA-phosphorylated GMF, although a small increase in function was noted
when the three kinases were combined. However, a bigger change was seen when PKA was used together with PKC, showing an increment in GMF function larger than the sum of their individual effects, indicating the presence of synergism.
To find out which kinases in the cell are potentially capable of
phosphorylating GMF, we performed an "in-gel" kinase assay. In this
procedure, C6 rat glioma cells were stimulated with PMA, and the cell
lysate was subjected to SDS-polyacrylamide gel electrophoresis using a
piece of gel embedded with recombinant GMF. After electrophoretic separation, the protein bands capable of phosphorylating GMF were revealed by incubation with 32P-labeled ATP and
autoradiography. Fig. 4 shows that there were at least
three defined protein bands capable of phosphorylating GMF, two of
which were identical in electrophoretic mobility with PKA and PKC,
whereas a third band was unidentified. Although the results may not
necessarily reflect the in vivo situation, when taken
together with our earlier findings that phorbol ester (activator of
PKC) and forskolin (activator of PKA) stimulate the phosphorylation of
endogenous GMF in live cells (4, 6), a strong argument can be made for
the activation of endogenous GMF by endogenous PKC and PKA.
To gain an insight into the nature of the phospho-isoforms of GMF created by the action of PKA, PKC, RSK, and CKII, an experiment was conducted where synthetic GMF peptide fragments carrying single putative phosphorylation sites were tested as substrates for each of the four kinases (Table I). Peptide I contains threonine 26, which fits the R(R/K)X(S/T) consensus for PKA (10) and the RXRXX(S/T) consensus for RSK; peptide II contains serine 52, which fits the (S/T)XXEX consensus for CKII (11); peptide III contains serine 71, which fits the (S/T)X(K/R) consensus for PKC (11)); peptide IV contains serine 82, which fits the RX(S/T) consensus for PKA (11). The results of the experiment confirmed that threonine 26 is a target for both PKA and RSK, that serine 52 is for CKII, that serine 71 is for PKC, and that serine 82 is for PKA. In other words, PKA appears to phosphorylate at two sites, whereas the other three kinases phosphorylate at single sites, assuming that the four peptides cover all the targets for the four kinases. Except for an overlap between PKA and RSK at threonine 26, there are no overlaps among other kinases.
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The results of peptide phosphorylation are in conformity with our previous phosphoamino acid analysis, demonstrating the formation of phosphoserine as a result of PKC and CKII action on intact GMF, and the formation of phosphothreonine as a consequence of RSK action (4). However, a discrepancy exists with PKA in that we formerly detected phosphoserine but not phosphothreonine (4). We believe this was due to incomplete hydrolysis of the PKA-phosphorylated GMF, resulting in the release of phosphoserine but not phosphothreonine. A search of literature (12) revealed that the release of phosphoserine is virtually complete (94%) with a 1-h acid hydrolysis, whereas the release of phosphothreonine peaks at 4 h, and even so, the release is only partial (14%). In fact, we have now verified the time-dependent release of the two phosphoamino acids from PKA-phosphorylated GMF (results not shown).
By correlating the data on peptide phosphorylation with the in vitro effects of the GMF-P isoforms, one may speculate which of the putative sites is essential for which function. For example, PKA and RSK share the Thr26 site, but the Ser82 site is unique to PKA. Because only PKA- but not RSK-phosphorylated GMF can enhance the activity PKA, it appears that Ser82, either alone or in combination with Thr26 (to be determined), is responsible for PKA activation. On the other hand, because the PKC target site does not overlap the PKA sites, yet PKC-phosphorylated GMF also activates PKA, it appears that the Ser71 site alone is also sufficient for activating PKA. That both Ser82 and Ser71 sites are independently involved in PKA activation is consistent with the fact that double phosphorylation of GMF by PKA and PKC showed synergistic effect (Fig. 3). Likewise, among the isoforms of GMF-P, only the PKA-phosphorylated form can enhance the activity of p38. Therefore, it appears that the S82 site (unique to PKA) is necessary for p38 activation. Whether it requires the participation of T26 remains to be seen. The inhibition of ERK activity is shared by PKA- and RSK-phosphorylated GMF. We, therefore, speculate that perhaps the T26 site is both necessary and sufficient for ERK inhibition.
Although the information is far from complete, our study on synthetic peptides does reveal important clues to the structure-function relationship of GMF-P isoforms. Future work with phosphopeptide analysis (from intact GMF protein) and site-directed mutagenesis (where putative phosphorylation sites are substituted) should provide a more definitive conclusion.
In many cell types, PKA suppresses the Ras/ERK transduction pathway by phosphorylating and inactivating Raf (two steps upstream of ERK)(13, 14). We found previously that PKA can potentially suppress the Ras/ERK pathway in another manner, i.e. by phosphorylating GMF which then inhibits ERK (5). In this regard, the positive feedback of PKA-phosphorylated GMF on the activity of PKA as reported in this paper takes on additional meaning. Because the major role of endogenous GMF appears to be a bifunctional regulator of the MAP kinase cascades (inhibition of ERK and promotion of p38), one can speculate that the mutual augmentation between GMF and PKA serves to maximize the influence of PKA on the regulation of MAP kinase by GMF. In addition, the phosphorylation of GMF by PKC provides yet another trigger for the activation of GMF by PKA. The fact that the IC50 of GMF-P on ERK and the EC50 of GMF-P on p38 and PKA all fall within the same lower nanomolar range implies that the multiple interplays can take place simultaneously (barring compartmentation).
In the nervous system, the PKA pathway conveys messages imparted by the neurotransmitters and neuropeptides, whereas the ERK MAP kinase cascade channels information from the neurotrophins and other growth factors. More recently, the Janus kinase/signal transducer and activator of transcription (Jak/STAT) pathway emerges as another signaling traffic important in the nervous system, relaying messages from the neuropoietic cytokines, such as ciliary neurotrophic factor and leukemia inhibitory factor (15, 16). Furthermore, the Jak/STAT pathway has been found to elicit exploratory behavior initiated by leptin (17, 18). Because ERK is essential for the activation of STAT (19, 20), we expect endogenous GMF to be able to regulate the Jak/STAT pathway as well. Thus, by modulating and integrating the functions of several major signal transduction cascades, GMF and its various phospho-isoforms inside the cell could have far-reaching significance both in general cell biology and in neuroscience.
We thank Christine J. Darby and Brian D. Fink for technical assistance.