(Received for publication, January 16, 1997, and in revised form, April 23, 1997)
From the Laboratory of Antibiotics, The Institute of Physical and Chemical Research (RIKEN), 2-1 Hirosawa, Wako, Saitama 351-01, Japan
Staurosporine, a protein kinase inhibitor, is known to mimic the effect of nerve growth factor (NGF) in promoting neurite outgrowth. To elucidate the mechanism by which staurosporine induces neurite outgrowth in PC-12 cells, we performed an in-gel kinase assay using myelin basic protein as a substrate, and found that staurosporine induced the activation of a kinase with an apparent molecular mass of 57 kDa. The dose of staurosporine required to activate this kinase was consistent with that required to induce neurite outgrowth. Interestingly, the staurosporine-activated kinase was immunoprecipitated by anti-c-Jun NH2-terminal kinase (JNK) isoforms antibody, but not by anti-JNK1-specific antibody or anti-ERK1 antibody, raising the possibility that this kinase is a novel JNK isoform. The substrate specificity of the kinase was distinct from those of osmotic shock-activated JNKs and NGF-activated ERK1. The kinase phosphorylates transcription factors including c-Jun, Elk-1, and ATF2, as well as myelin basic protein, suggesting that it plays a role in gene induction. Furthermore, staurosporine induced immediate-early genes including Nur77 and fos, but not jun. The activation of the staurosporine-activated kinase, as well as the induction of neurite outgrowth, did not require Ras function, while Ras was required for the activation of ERKs and neurite outgrowth induced by NGF. Taken together, these results indicate staurosporine specifically activates a JNK isoform, which may contribute to biological activities including neurite outgrowth.
Neurotrophic factors play a key role in the normal development of the nervous system by regulating both differentiation and apoptosis of neurons (1). Nerve growth factor (NGF)1 is the prototype of this family of neurotrophins and its intracellular signaling pathways have been intensely studied using rat pheochromocytoma PC-12 cells, which undergo neuronal differentiation in response to NGF stimulation (1, 2). NGF binds and activates its receptor, Trk, which leads to the activation of a guanine nucleotide-binding protein, Ras (3-5). Expression of oncogenic Ras in PC-12 cells induces neuronal differentiation (6), while introduction of anti-Ras antibody or dominant inhibitory Ras mutant into PC-12 cells blocks NGF-induced differentiation (7, 8), suggesting that Ras is necessary and sufficient for neuronal differentiation in PC-12 cells. The formation of GTP-Ras is followed first by the activation of Raf and then by activation of MEK (9, 10). MEK in turn activates the ERK family of MAP kinases, which then phosphorylate a variety of proteins including Elk-1 transcription factor (11-13). The expression of a dominant inhibitory mutant of Ras inhibits activation of the Raf/MEK/ERK kinase cascade (14-16). Furthermore, recent studies revealed that MEK and ERK play an important role in NGF-induced differentiation (17, 18). These results indicate the Ras/Raf/MEK/ERK signaling pathway plays a key role in NGF-induced differentiation in PC-12 cells.
The molecular cloning of c-Jun NH2-terminal kinases (JNKs), also termed stress-activated protein kinases, led to the identification of JNKs as a member of the MAP kinase family of protein kinases (19-21). JNKs are activated by inflammatory cytokines and cellular stresses including ultraviolet irradiation, osmotic shock, and treatment with protein synthesis inhibitors, while ERKs are activated by growth factor stimulation (22-25). Activation of JNKs requires the phosphorylation of JNK on Thr and Tyr, which is mediated by a dual specificity protein kinase (19). One of the JNK activators, MKK4 is activated by phosphorylation by another protein kinase, MEKK1 (26, 27). Although the mechanism of MEKK1 activation is not fully understood, it appears that the signaling pathway leading to the activation of JNKs is distinct from the Ras/Raf/MEK signaling pathway, which is responsible for the activation of ERKs.
Recent studies identified 10 isoforms of JNKs (28). These isoforms arise from the alternative processing of transcripts from three different genes: those for JNK1, JNK2, and JNK3. Although similar in amino acid sequences, these JNK isoforms have distinct in vitro biochemical properties, suggesting they are not functionally redundant. Consistent with this, it has been shown that JNK1, but not JNK2, complements a defect in the expression of the MAP kinase, HOG1 in the yeast Saccharomyces cerevisiae (21).
A number of chemical compounds have been reported to induce neurite outgrowth. In this study, we investigated staurosporine-induced neurite outgrowth, and found staurosporine activated a protein kinase with an apparent molecular mass of 57 kDa. Interestingly, the staurosporine-activated kinase was recognized by anti-JNK isoforms antibody, but not by anti-JNK1-specific or anti-ERK1-specific antibody, suggesting this kinase is a JNK. However, the apparent molecular mass of this kinase was different from those of osmotic shock-activated JNKs whose molecular masses were 46 and 55 kDa. Interestingly, staurosporine did not activate osmotic shock-activated kinases, and conversely, osmotic shock did not induce the staurosporine-activated kinase activation. Furthermore, the substrate specificity of the staurosporine-activated kinase was different from that of JNK1 and ERK1. Taken together these results indicate that staurosporine specifically activates a JNK-related kinase, which is different from well characterized stress-activated JNKs. The staurosporine-activated kinase has a distinct substrate specificity, raising the possibility that it is involved in distinct biological activity including differentiation.
PC-12 cells were maintained in Dulbecco's modified Eagle's medium supplemented with 5% fetal bovine serum and 5% calf serum. PC-12 cells expressing RasN17 (M-M17-26 cells, provided by Geoffrey M. Cooper (Dana-Farber Cancer Institute, Harvard Medical School, Boston, MA) (8) were maintained in Dulbecco's modified Eagle's medium supplemented with 5% fetal bovine serum, 5% calf serum, and 400 µg/ml G418.
Preparation of Recombinant ProteinThe GST-c-Jun, GST-Elk-1, and GST-ATF2 expression plasmids were provided by Roger J. Davis (University of Massachusetts, Worcester). These plasmids were expressed in a bacteria strain, BL21(DE3), and GST fusion proteins were purified by glutathione chromatography as described (29).
In-gel Kinase AssayIn-gel kinase assay was performed
essentially as described previously (30). Subconfluent dishes of PC-12
cells or PC-12 cells expressing RasN17 were lysed in MAP kinase
extraction buffer, and the protein concentration was determined by
Bio-Rad protein assay. To assay total cell lysate, equal amounts of
protein (50-100 µg) were electrophoresed in 10% SDS-polyacrylamide
gels containing either myelin basic protein (MBP) (0.5 mg/ml),
GST-c-Jun (1-79) (0.1 mg/ml), GST-ATF2 (0.1 mg/ml), or GST-Elk-1 (0.1 mg/ml) as a substrate. For immunoprecipitation, the NaCl concentration
of the cell extract was adjusted to 150 mM, 2 µg of each
antibody was added to 100 µl of cell extract containing 500 µg of
protein, and incubation carried out for 1 h at 4 °C. Anti-JNK
isoforms antibody and anti-ERK1 antibody were purchased from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA). Anti-JNK1-specific antibody was
purchased from PharMingen (San Diego, CA). Next, 50 µl of 10%
protein A-Sepharose was added and the mixture incubated for 1 h at
4 °C. Protein A-Sepharose beads were collected by centrifugation and
washed four times with MAP kinase extraction buffer. SDS-polyacrylamide gel electrophoresis sample buffer was added to protein A-Sepharose beads and samples were electrophoresed in SDS-polyacrylamide gels containing various substrates as indicated. Following electrophoresis, SDS were removed from the gel, protein was renatured, and a kinase assay was carried out by incubating the gel in buffer containing [-32P]ATP. Gels were washed, and incorporated
radioactivity was quantified using an image analyzer (BAS2000, Fuji
Film Co. Ltd., Japan).
Total cytoplasmic RNA was isolated as described (31). RNAs (15 µg) were electrophoresed in 1% formaldehyde-agarose gels and transferred to Biodyne-B membrane (East Hills, NY). Filters were prehybridized, hybridized and washed according to the manufacturer's instructions. The following DNA fragments were 32P-labeled with a random priming kit (Life Technologies, Inc.) for use as probes: fos, a 1-kb PstI fragment from pfos-1 (32); jun, a 0.9-kb PstI fragment of human jun (33); Nur77, a 1.9-kb EcoRI-KpnI fragment from a pGEM-Nur77 construct (34).
We
studied differentiation in PC-12 cells induced by chemical compounds
and found that staurosporine was a potent inducer of neurite outgrowth.
As reported (35, 36), staurosporine induced neurite outgrowth at
concentrations of as low as 4-20 ng/ml, with maximal induction
obtained at 100 ng/ml (Fig. 1). Staurosporine induced
neurite outgrowth faster than NGF. After 6 h of staurosporine
treatment, small neurites were observed. Maximal neurite outgrowth was
obtained after 24 h of treatment, and was comparable to that
obtained by 3 days of treatment with NGF. We also tested K-252a, a
staurosporine-related compound that exhibits similar effects on a
variety of kinases, and found that K-252a did not induce neurite
outgrowth at a similar range of concentration (date not shown).
Staurosporine Activates a Kinase with an Apparent Molecular Mass of 57 kDa
Since ERK1 and ERK2 of the MAP kinase family have been
shown to play an important role in NGF-induced differentiation (18), we
tested whether staurosporine can induce MAP kinases. To this end, we
conducted an in-gel kinase assay using MBP as a substrate (Fig.
2). Consistent with previous reports (30), NGF strongly induced ERK1 and ERK2 at 5 min after stimulation and the activity decreased with time. Interestingly, staurosporine induced a kinase with
an apparent molecular mass of 57 kDa (Fig. 2A). When MBP was
omitted from the gel, this band was not detected, indicating the
phosphorylation was not due to autophosphorylation (data not shown). In
contrast to the rapid and transient NGF-induced activation of ERKs,
staurosporine induced a prolonged activation of the 57-kDa kinase (Fig.
2B). Weak activation was observed at 5 min after stimulation, and maximal activation was obtained at 120 min after stimulation. Weak activation of the kinase was induced with
staurosporine treatment as low as 4 ng/ml, while maximal activation was
obtained at a concentration of 100 ng/ml (Fig. 2C).
Differences in molecular mass indicate that the staurosporine activated
kinase is distinct from ERK1 and ERK2, both of which are thought to be
involved in NGF-induced differentiation. However, the concentration of
staurosporine required for the activation of the 57-kDa kinase was
similar to that required for the induction of neurite outgrowth,
raising the possibility that the 57-kDa kinase plays a role in
staurosporine-induced neurite outgrowth. Consistent with this, K-252a,
a compound similar to staurosporine in its structure and biological
activities in inhibiting kinases, did not induce neurite outgrowth and
did not induce the activation of the 57-kDa kinase (date not
shown).
The Staurosporine-activated Kinase Was Recognized by Anti-JNK Isoforms Antibody
The MAP kinase family is part of a large family
of serine-threonine protein kinases (19-21). Since JNKs are a
subfamily of the MAP kinase family, we tested whether the
staurosporine-activated kinase belongs to the JNK subfamily. To this
end, we used three antibodies. 1) Anti-JNK isoforms antibody was raised
against a full length recombinant protein of JNK2, and recognizes JNK1
and JNK2. 2) Anti-JNK1-specific antibody recognizes only JNK1. 3) Anti-ERK1 antibody recognizes ERK1 specifically. Using these
antibodies, we immunoprecipitated JNKs and ERK1 from cells treated with
either NGF, staurosporine or osmotic shock and tested for their kinase activities using an in-gel kinase assay (Fig. 3). As
expected, NGF induced kinases with molecular masses of 42 and 44 kDa,
and the 44-kDa kinase was recognized by anti-ERK1 antibody, but not by
anti-JNK isoforms antibody or anti-JNK1-specific antibody, indicating
NGF specifically activates ERK1 and ERK2. Osmotic shock, induced by
treatment of cells with 0.5 M sorbitol for 30 min, induced
the activation of kinases with molecular masses of 46 and 55 kDa, which
probably represent mixtures of JNK1 and JNK2 (28). Consistent with
this, these kinases were recognized by anti-JNK isoforms antibody and
anti-JNK1-specific antibody, but not by anti-ERK1 antibody. Anti-JNK
isoforms antibody only recognized the 55-kDa isoform of JNKs, which is
probably due to the preferential recognition of the COOH-terminal
region of JNKs by this antibody. The kinase activated by staurosporine
was recognized by anti-JNK isoforms antibody, but not by
anti-JNK1-specific antibody or anti-ERK1 antibody. Note that the
staurosporine-activated kinase has a slower mobility in
SDS-polyacrylamide gel compared with those activated by osmotic shock,
indicating they are distinct kinases (Figs. 3 and 4).
Furthermore, the 57-kDa kinase was the only kinase induced by
staurosporine treatment.
Although the staurosporine-activated kinase was recognized by anti-JNK isoforms antibody, it is possible that the signal detected by an in-gel kinase assay represented multiple kinase activities. To test this possibility, we analyzed the staurosporine-treated cell extract by chromatography using a Mono Q column. Since only a single peak of 57-kDa kinase activity was identified (data not shown), it is therefore unlikely that the 57-kDa kinase activity detected by an in-gel kinase assay contains multiple kinase activities.
Taken together, these results indicate that staurosporine specifically activates a kinase that is immunologically related to JNKs, but is distinct from JNK1 and JNK2.
The Staurosporine-activated Kinase Has Different Substrate SpecificityIt has been reported that ERKs and JNKs have a different substrate specificity, which is thought to contribute to their distinct biological activities. We therefore determined the substrate specificity of the staurosporine-activated kinase (Fig. 4). As expected, ERK1 that was activated by NGF efficiently phosphorylated MBP and Elk-1. In contrast, JNK1 activated by osmotic shock strongly phosphorylated ATF2, and, to a lesser extent, Elk-1 and c-Jun. However, the staurosporine-activated kinase phosphorylated MBP, Elk-1, ATF2, and c-Jun. These results indicate that, although the staurosporine-activated kinase is related to JNKs, it has a different substrate specificity to JNK1 and ERK1.
Staurosporine Induces Transcription of Nur77 and fos, but Not jun GenesBoth ERKs and JNKs are believed to regulate gene expression
by phosphorylating transcription factors (37). Similarly, the staurosporine-activated kinase was able to phosphorylate several transcription factors. However, since the staurosporine-activated kinase had a distinct substrate specificity, we tested whether staurosporine can induce transcription of early response genes including Nur77, fos, and jun (Fig.
5). Interestingly, staurosporine induced
Nur77 and fos transcription. Quantitation of the
induction indicated that the induction of Nur77 by
staurosporine was 2.9-fold at 3 h after stimulation, while that by
NGF was 12.8-fold at 45 min after stimulation. Similarly, staurosporine
induced fos transcription by 1.9-fold after 2 h of
stimulation, while NGF induced fos transcription by 8.0-fold
after 45 min of stimulation. Although the induction of Nur77
and fos by staurosporine was smaller than that of NGF, the
induction of these genes by staurosporine is significant, because
jun was not induced by staurosporine. It is worthy to note
that staurosporine induced prolonged transcriptional activation with a
maximal activation at 180 min after treatment, while NGF-induced transcriptional activation was more rapid and transient. Thus it
appears staurosporine induces transcriptional activation of early
response genes, but the induction was different from that by NGF with
respect to spices of genes and time course of the induction.
Involvement of Ras in the 57-kDa Kinase Activation and Neurite Outgrowth Induced by Staurosporine
It has been shown that the
signaling pathways leading to the activation of ERKs and JNKs are
distinct (27). Since Ras function is necessary for the NGF-induced
activation of ERKs as well as the NGF-induced neurite outgrowth, we
investigated whether Ras is required for activation of the 57-kDa
kinase and neurite outgrowth in PC-12 cells induced by staurosporine
(Fig. 6). As previously reported (14, 15), NGF did not
induce activation of ERKs in dominant inhibitory mutant Ras
(RasN17)-expressing PC-12 cells. In contrast, staurosporine did
activate the 57-kDa kinase in RasN17-expressing PC-12 cells to an
extent similar to that in wild type PC-12 cells. Similarly, Ras
function was not required for the activation of JNKs induced by osmotic
shock.
Similar results were obtained in neurite outgrowth in PC-12 cells (Fig.
7). RasN17 interfered with NGF-induced neurite
outgrowth, but not staurosporine-induced neurite outgrowth. These
results suggest that staurosporine and NGF induce neurite outgrowth via distinct signaling pathways.
ERK1 and ERK2 of the MAP kinase family play a key role in
NGF-induced neuronal differentiation in PC-12 cells. Since
staurosporine is a potent inhibitor of protein kinases and also an
inducer of neurite outgrowth in PC-12 cells, in this study, we first
investigated whether staurosporine activates the signaling pathway that
leads to the activation of members of the MAP kinase family.
Interestingly, we found that staurosporine activated a kinase detected
by an in-gel kinase assay using MBP as a substrate. This kinase
differed from known ERKs in molecular mass, and in that it was not
recognized by anti-ERK1-specific antibody. However, it was recognized
by anti-JNK isoforms antibody, which recognizes JNK1, JNK2, and
probably other isoforms of JNKs. Therefore it is most likely that this staurosporine-activated kinase is a JNK. The finding that staurosporine activates a member of the JNK family is consistent with a previous report (38). However, the molecular mass of the kinase is 57 kDa, which
is distinct from those of well characterized JNKs activated by various
stimuli including osmotic shock (Figs. 3 and 4). Furthermore, the
substrate specificity of the kinase was also distinct (Fig. 4). Recent
detailed analysis led to the identification of 10 different JNK
isoforms that arise from the alternative processing of transcripts from
three different genes (28). It turned out that the JNKs with the
molecular mass of 46 and 55 kDa represented a mixture of JNK isoforms.
Thus it is possible that the staurosporine-activated kinase is a novel
JNK isoform. Consistent with this, anti-JNK1-specific antibody did not
recognize the staurosporine-activated kinase. However, we cannot
exclude the possibility that this kinase is identical to JNK3-2,
which has a molecular mass of 57 kDa (28). If this is the case, our
paper is the first to describe the activation and the distinct
substrate specificity of JNK3-
2.
Since staurosporine inhibits a variety of kinases including the ERKs of the MAP kinase family, it is unlikely that staurosporine activates the 57-kDa kinase by a direct interaction. Members of the MAP kinase family of protein kinases are known to be activated by several signaling pathways. It is interesting to note that staurosporine did not activate JNKs having molecular masses of 46 and 55 kDa. Conversely, osmotic shock failed to activate the 57-kDa kinase. It thus appeared that the signaling pathway leading to the activation of the 57-kDa kinase is specifically activated by staurosporine. It has been shown that JNKs become active only when a Thr and a Tyr residue in a Thr-Pro-Tyr motif are phosphorylated (19). Although a kinase, MKK4, was identified as being responsible for this phosphorylation (26), the involvement of several other JNK kinases has also been suggested (39, 40). It is established that ERKs and JNKs are activated by distinct signaling pathways as defined by MAP kinase kinases (also termed MKKs or SAPKs) (41-43). However, to our knowledge, no specific signaling pathway that distinguishes JNK isoforms has been reported. Staurosporine specifically activates the 57-kDa kinase. Thus, we conclude by suggesting that staurosporine activates a specific kinase cascade which leads to the activation of the 57-kDa kinase, but not other isoforms of JNKs.
Staurosporine was originally considered to be a specific inhibitor of protein kinase C, but further studies revealed it also inhibits a variety of tyrosine kinases as well as serine-threonine kinases. At this point, it is not clear whether the inhibition of kinase(s) contributes to the activation of the 57-kDa kinase. However, a structurally related compound, K-252a, which also inhibits protein kinases, did not activate the 57-kDa kinase (data not shown). Similarly, K-252a did not induce neurite outgrowth in PC-12 cells (data not shown; Ref. 35). These results suggest the action of staurosporine to induce the 57-kDa kinase activation and neurite outgrowth is not due to the inhibition of kinases. Staurosporine did not activate ERK1 and ERK2 of MAP kinases, which play an important role in NGF-induced differentiation. However, the 57-kDa kinase activated by staurosporine phosphorylated MBP and ERK1, which suggests the 57-kDa kinase can phosphorylate and activate common downstream target(s) to ERKs. Furthermore, the concentrations required for the activation of the 57-kDa kinase and for the induction of neurite outgrowth are almost the same, which suggest the involvement of the 57-kDa kinase in the induction of neurite outgrowth. This conclusion is supported by experiments using a compound, K-252a, which is structurally similar to staurosporine and also has similar inhibition profile on a variety of kinases. Despite these similarities, K-252a did not induce neurite outgrowth, and importantly, failed to activate the 57-kDa kinase. The MAP kinases are part of a large family of serine-threonine protein kinases. However, their physiological roles are thought to be distinct. For example, ERKs are thought to play a key role in the differentiation of PC-12 cells, while JNKs may play a role in induction of apoptosis (18, 38). Consistent with this, the substrate specificities of these kinases are different. MBP is effectively phosphorylated by ERK1, while ATF2 was strongly phosphorylated by JNK1. Interestingly, the staurosporine-activated 57-kDa kinase phosphorylated both MBP and ATF2 as well as Elk-1 and c-Jun, suggesting the staurosporine-activated kinase may have similar but distinct biological roles. Consistent with this, staurosporine induced transcriptional activation of Nur77 and fos, but not jun. Furthermore, although staurosporine induces neurite outgrowth in PC-12 cells, it also has been reported that apoptosis was induced by staurosporine under certain conditions (38). In Drosophila, recent studies revealed that a JNK homolog mediates cell morphogenesis and an immune response (44, 45). Further studies will be necessary to identify the biological significance of the staurosporine-activated kinase.
We are grateful to R. Davis for providing plasmids encoding GST-c-Jun, GST-ATF2, and GST-Elk-1. We also thank T. Endo, T. Sudo, and T. Usui for their helpful suggestions.