p38-2, a Novel Mitogen-activated Protein Kinase with Distinct Properties*

(Received for publication, January 10, 1997, and in revised form, March 14, 1997)

Bernd Stein Dagger §, Maria X. Yang Dagger , David B. Young Dagger , Ralf Janknecht par , Tony Hunter , Brion W. Murray Dagger and Miguel S. Barbosa Dagger

From Dagger  Signal Pharmaceuticals Inc., San Diego, California 92121 and  The Salk Institute, Molecular Biology and Virology Laboratory, San Diego, California 92186

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Mitogen-activated protein (MAP) kinases are involved in many cellular processes. Here we describe the cloning and characterization of a new MAP kinase, p38-2. p38-2 belongs to the p38 subfamily of MAP kinases and shares with it the TGY phosphorylation motif. The complete p38-2 cDNA was isolated by polymerase chain reaction. It encodes a 364-amino acid protein with 73% identity to p38. Two shorter isoforms missing the phosphorylation motif were identified. Analysis of various tissues demonstrated that p38-2 is differently expressed from p38. Highest expression levels were found in heart and skeletal muscle. Like p38, p38-2 is activated by stress-inducing signals and proinflammatory cytokines. The preferred upstream kinase is MEK6. Although p38-2 and p38 phosphorylate the same substrates, the site specificity of phosphorylation can differ as shown by two-dimensional phosphopeptide analysis of Sap-1a. Additionally, kinetic studies showed that p38-2 appears to be about 180 times more active than p38 on certain substrates such as ATF2. Both kinases are inhibited by a class of pyridinyl imidazoles. p38-2 phosphorylation of ATF2 and Sap-1a but not Elk1 results in increased transcriptional activity of these factors. A sequential kinetic mechanism of p38-2 is suggested by steady state kinetic analysis. In conclusion, p38-2 may be an important component of the stress response required for the homeostasis of a cell.


INTRODUCTION

Several signaling cascades targeting different mitogen-activated protein kinases (MAPKs)1 have been identified over the last few years in yeast and vertebrates (1-9). The members of the MAPK family are proline-directed Ser/Thr kinases which themselves are activated upon phosphorylation on Thr and Tyr by dual specificity protein kinases, the MAPK kinases (MAPKKs). Specific protein kinase cascades (MAPKKKright-arrow MAPKKright-arrowMAPK) constituted within the cytoplasm are stimulated by a variety of signals including growth factors, cytokines, ultraviolet light (UV), and other stress-inducing agents. Since these signals can affect cell proliferation, oncogenesis, development as well as differentiation, and the cell cycle, MAPKs may have a pivotal impact on these cellular processes.

The p38MAPK (cytokine-suppressive anti-inflammatory drug binding protein; CSBP1/2) was identified by homology to the yeast HOG1 MAPK and is activated by osmotic shock (10-12). Proinflammatory cytokines, lipopolysaccharide, and chemical stress such as H2O2 also can induce p38MAPK (10, 11, 13-19). An important role of p38 in cellular responses involving cytokine production and platelet aggregation was established from studies in which p38 was specifically inhibited by the pyridinyl imidazole derivative SB203580 (19-21).

Several substrate proteins for p38 have been identified, among them the transcription factors ATF2, CHOP-1, and Elk1 and the protein kinases MAPKAP K2/3 (14, 16, 22-24). Furthermore, a truncated splice variant of p38 with a distinct C terminus (Mxi2) phosphorylates the transcription factor Max (25). p38 itself is phosphorylated and thereby activated by the MAPKKs MKK3 (26), JNKK (26, 27), and the recently discovered MEK6 (22, 28, 29). Furthermore, several candidates (MEKK1, Pak1, DLK, TAK1) for an upstream protein kinase (MAPKKK) for this cascade have been described (27, 30-33).

In an attempt to find novel members of the p38MAPK cascade, we cloned and characterized a new human MAPK, which we named p38-2. Analysis of various tissues demonstrated that p38-2 is differently expressed from p38. Like p38, p38-2 is activated by stress-inducing signals and cytokines. We show that MEK6 phosphorylates p38-2, suggesting its role as a specific MAPKK. Although p38-2 and p38 phosphorylate the same substrates, the site specificity of phosphorylation can differ, and p38-2 appears to be about 180 times more active on certain substrates such as ATF2.


EXPERIMENTAL PROCEDURES

cDNA Cloning

The expressed sequence tags (EST) subdivision of the National Center for Biotechnology Information (NCBI) GenBank data base was searched with the tblastn program and the human p38 (CSBP) amino acid sequence as query. The 154-bp EST sequence R72598 from a human breast cDNA library displayed the highest similarity score. A forward PCR primer (5'-GCGCCAGGCGGACGAGGAGATGACC-3') directed against the 3' end of this sequence was designed with the help of the program Oligo version 4.0 (National Biosciences, Inc.). This gene-specific forward primer and the adaptor-specific primer from the Marathon cDNA Amplification Kit (CLONTECH) were used to PCR-amplify the 3' portion of p38-2 from a skeletal muscle cDNA library (CLONTECH). PCR amplification was performed with a combination of Taq and Pwo polymerases (Expand Long Template PCR System, Boehringer Mannheim) in the presence of TaqStart antibody (CLONTECH). All PCR amplifications were carried out in 0.2 ml of Perkin-Elmer thin wall MicroAmp tubes and a Perkin-Elmer model 2400 or 9600 thermocycler. The resulting 800-bp PCR fragment was ligated into pGEM-T (Promega) and sequenced (dye terminator cycle sequencing) with an ABI 373 Automated Sequencer (Applied Biosystems, Foster City, CA). We also sequenced the original R72598 clone. This clone had a 900-bp insert encoding the 5' end of p38-2. We recombined the cDNA insert of R72598 and the 3' end of one of the p38-2 clones by restriction digest using a unique KpnI site. The resulting 1.5-kb cDNA was ligated into 3xHA-BKS and its sequence determined. The BLAST program was used to search the NCBI GenBank data base for related cDNAs. The Bestfit program from the Wisconsin Genetics Computer Group, Madison, WI, was used for calculating the amino acid identities between p38 and p38-2. The MacVector program (Oxford Molecular Group) was used for aligning the sequences of p38 and p38-2.

Plasmids and Reagents

3xHA-p38-2-SRalpha 3 was constructed by replacing serine in position 2 of p38-2 with alanine, adding sequence encoding three copies of a 10-amino acid hemagglutinin (HA) epitope to the N terminus of p38-2 and ligating the resulting cDNA into SRalpha 3. GST-p38-2 was constructed by ligating a 1.1-kb DNA fragment encoding amino acid 1 through the stop codon of p38-2 with a serine to alanine substitution in position 2 into pGEX-KG (34). 3xHA-MEK6(DD)-SRalpha 3 was constructed by PCR mutagenesis of the wild type MEK6 expression vector (29) replacing the phosphorylation motif SVAKT with DVAKD. The following plasmids have been described previously: HA-JNK1 (35), HA-ERK1 (36), HA-TAK1, HA-TAK1-Delta N, HA-TAK1-K63W (33), CMV5-MEKK1 (37), CMV-Elk12-428 (38), CMV-Sap-1a1-431 (39), His-ERK1(K52R) (40), GST-c-Jun1-79 (41), GST-ATF2 (42), GST-Elk1307-428 (43), GST-Sap-1a268-431 (44), GST-p65 (45), GST-p50 (45), GST-C/EBPbeta (46), GST-ER (47), pEV3S (48), SRE2-tk80-luc (38), GAL4-LUC (49), pAG147 (49), GAL4-ATF219-96 (49).

The pyridinyl imidazole derivative, SB203580 (50), was prepared at Signal Pharmaceuticals.

Northern Blot Analysis

Northern blots were performed using 2 µg of poly(A)+ RNA isolated from 16 different adult human tissues, fractionated by denaturing formaldehyde 1.2% agarose gel electrophoresis, and transferred onto a charge-modified nylon membrane (CLONTECH). The blots were hybridized to a p38 probe (850-bp CSBP2 cDNA fragment), p38-2 probe (900-bp p38-2 cDNA fragment), or p38-2 intron probe (oligonucleotide against first intron) using ExpressHyb (CLONTECH) according to the manufacturer's instructions. Both cDNA probes were prepared by random prime labeling (Prime It II, Stratagene) of the cDNA with [alpha -32P]dCTP (NEN Life Science Products). The oligonucleotide was end-labeled with [gamma -32P]dATP (NEN Life Science Products). For control purposes the blots were also hybridized to a radiolabeled beta -actin probe.

Transient Transfection and Extract Preparation

Cells were cultured in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum, 500 mg/liter L-glutamine, and antibiotics. HeLa cells were transfected using LipofectAMINE (Life Technologies, Inc.); COS cells were transfected using DMRIE-C (Life Technologies, Inc.); and 293 cells were transfected by the calcium phosphate coprecipitation method (51). Twenty-four hours later cells were treated with stimulators of MAPK for 45 min unless otherwise indicated and then solubilized in kinase lysis buffer as described (35). Protein concentration of lysates was determined by Bradford assay (52). HA-tagged proteins were isolated from transfected cells with an anti-HA antibody (Boehringer Mannheim).

Reporter Gene Assays

293 cells were transiently transfected by the calcium phosphate coprecipitation method with the SRE2-tk80-luc luciferase reporter gene construct and either the empty expression vector pEV3S or the respective expression vector for Elk1 or Sap-1a as well as the indicated protein kinase vectors. Luciferase activity was determined 36 h after transfection and normalized to transfection efficiency with the help of a cotransfected beta -galactosidase expression vector (38). HeLa cells were transiently transfected with the 5×GAL4-luc reporter gene construct and either the empty expression vector pAG147 or GAL4-ATF219-96 as well as the indicated kinase vectors.

Protein Expression, Purification, and Protein Kinase Assays

Expression of bacterial GST-fusion proteins and purification by affinity chromatography on GSH-Sepharose 4B beads (Pharmacia Biotech Inc.) was performed as described previously (46). Kinase assays were performed as described previously (29).

Phosphopeptide Analysis

In vitro phosphorylated GST-fusion proteins were subjected to SDS-PAGE. The gel was dried and exposed to an x-ray film, and a gel slice containing the phosphorylated GST-fusion protein was cut out. The protein was extracted from the gel slice as described (53). After digestion with chymotrypsin, the resulting phosphopeptides were resolved on cellulose thin layer plates by electrophoresis in the first dimension in pH 1.9 buffer (88% w/v formic acid/glacial acetic acid/water, 50:156:1794) and by ascending chromatography in 1-butanol/pyridine/glacial acetic acid/water (15:10:3:12) in the second dimension (53).

Kinetic Evaluation of p38-2

The p38-2 reaction velocities were determined by quantifying the amount of 32P incorporation into GST-ATF2. GST-p38-2 activity was monitored as a function of both GST-ATF2 concentration (0.31, 0.62, 1.25, 2.5, and 5.0 µM) and ATP concentration (0.05, 0.5, 2.5, and 5.0 µM). Enzymatic reactions (0.1 ml) were carried out in wells of a 96-well assay plate (Corning) for 1 h at room temperature and terminated with the addition of trichloroacetic acid (150 µl/well of 12.5% w/v). The subsequent 20-min incubation with trichloroacetic acid at 4 °C precipitated the proteins from solution. The trichloroacetic acid-mediated precipitate was then collected on 96-well glass fiber plates (Packard) and washed 10 × with approximately 0.3 ml per well of phosphate-buffered saline, pH 7.4, using a Packard Filtermate 196. Scintillation fluid (0.05 ml, MicroScint, Packard) was added to each well, and the plate was analyzed for 32P using a Packard TopCount scintillation counter. Reactions contained 20 µl of recombinant p38-2 (0.25 µg/ml in a dilution buffer that contained 20 mM HEPES, pH 7.6, 0.2 mM EDTA, 2.5 mM MgCl2, 0.004% Triton X-100, 2 mM dithiothreitol, 5 µg/ml leupeptin, 20 mM beta -glycerophosphate, 0.1 mM sodium vanadate), 25 µl of ATP solution (in distilled, deionized water), 18 µl of recombinant GST-ATF2 (in 20 mM HEPES, pH 7.6, 50 mM NaCl, 0.1 mM EDTA, 2.5 mM MgCl2, 0.5% Triton X-100), and 37 µl of a kinase buffer that delivered 0.5 µCi of [gamma -32P]ATP (Amersham Corp.) per reaction (in 20 mM HEPES, pH 7.6, 50 mM NaCl, 0.1 mM EDTA, 2.5 mM MgCl2, 0.5% Triton X-100, 2 mM dithiothreitol). A typical control reaction in the absence of GST-ATF2 that contained 722,808 cpm would result in a background of 584 cpm. The 32P-labeled GST-ATF2 typically ranged from 15,712 to 84,410 cpm which was significantly greater than the background and ensured accurate velocity values. Double reciprocal analysis was used to assess the kinetic mechanism. The data were fit to the equation for a sequential mechanism by nonlinear least squares method of Cleland (54) to obtain kinetic constants. The assay for p38-2 activity was a discontinuous assay with data taken after 1 h of room temperature reaction. The reaction time course of p38-2 was found to be linear up to and including 1 h of kinase reaction for the conditions used in the kinetic experiments. There is a linear relationship between enzyme activity and enzyme concentration for p38-2 concentrations from 6.1 to 49 nM. Less than 10% ATP was turned over in the course of the assay.

Kinetic Comparison of p38 and p38-2

The apparent kinetic constants for recombinant p38 and p38-2 were determined by the assay method described in the previous section. Data were taken in the linear portion of the reaction time course. Less than 10% ATP was turned over by p38 in the course of the assay. The final concentrations of GST-p38 and GST-p38-2 were 25 and 0.075 mg/ml, respectively. The GST-ATF2 concentration was varied (0.156, 0.313, 0.625, 1.25, and 2.50 µM). A common solution of GST-ATF2 was used for both p38 and p38-2 reactions. The ATP concentration in the kinase buffer was held constant at 15 µM. Reactions were initiated with the addition of a common kinase buffer that delivered 0.5 µCi of [gamma -32P]ATP (15 µM). After 1 h at room temperature, reactions (0.1 ml) were terminated and proteins were precipitated by the addition of 150 µl of 12.5% trichloroacetic acid (20 min incubation at 4 °C). Kinetic constants were derived from a nonlinear least squares fit to the Michaelis-Menten equation in the manner outlined by Cleland (54).


RESULTS

Isolation of p38-2 cDNA

We performed BLAST homology searches of the EST subdivision of NCBI GenBank data bank to identify EST sequences that encode peptides related to human p38MAPK (CSBP). A 154-bp EST fragment with the accession number R72598 that encoded a peptide related to p38 was identified. The corresponding cDNA clone was obtained from Research Genetics (clone ID 156272) and its sequence determined. The 900-bp cDNA fragment contained the putative 5' end of a novel gene. Although the cDNA fragment had an in-frame stop codon, the region before and after this stop codon encoded peptides with significant homology to p38.

A forward PCR primer was designed to amplify the missing 3' portion of the potential new gene from an adapter-ligated skeletal muscle cDNA library. A population of PCR fragments was obtained and subcloned into pGEM-T. Sequencing revealed several identical PCR clones with open reading frames followed by a stretch of about a 300-bp untranslated region and a poly(A)-tail. We combined the cDNA insert of R72598 with one of the PCR clones to obtain a cDNA of maximum length. A GenBank BLAST search revealed no identical sequences to this cDNA, and we named the respective gene p38-2, based on its similarity to p38.

Closer inspection of the sequence surrounding the internal stop codon and alignment of the encoded peptide with p38 revealed an 86-bp intron2 with typical splice junction consensus sequences. This suggests that the poly(A)+ selected mRNA preparation used for creation of the cDNA library contained unspliced mRNA. Therefore, we reamplified the intron area from a different skeletal muscle cDNA library. About 50% of the PCR clones had no intron, and about 25% had the previously described intron at amino acid position 102/103, and 25% had a different intron3 at amino acid position 149/150. From these data we conclude that p38-2 potentially exists in several isoforms. The 1.3-kb cDNA without introns encodes a protein of 364 amino acids with a calculated molecular mass of 41.3 kDa, and the cDNAs with intron 1 or intron 2 encode shorter proteins of 102 and 155 amino acids, respectively (Fig. 1A). Both shorter isoforms are missing the phosphorylation motif. p38-2 has 73% amino acid identity and 86% similarity with its closest homologue, p38. p38-2 is a member of the p38 subgroup of MAPK. A Clustal alignment of all five human p38 family members (p38-2, p38beta (55), p38 (12), Mxi2 (25), and ERK6 (56)) is shown in Fig. 1B. Relevant kinase subdomains are conserved as indicated by the shaded areas; all five kinases unlike other known MAPK have the TGY phosphorylation motif in the activation loop that is recognized by a MAPKK and have the same length of linker loop 12. 


Fig. 1. Primary structure of p38-2. A, primary amino acid sequences of full-length p38-2 and isoforms 1 and 2. * indicates the threonine and tyrosine in the TGY dual phosphorylation motif. The accession number for the p38-2 sequence is U92268. B, the MacVector program (Oxford Molecular Group) was used to perform a Clustal alignment of the amino acid sequences of human p38-2, p38beta , p38, Mxi2, and ERK6. Identical amino acid residues are darkly shaded, and conservative changes are lightly shaded.
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Tissue Distribution of p38-2

The expression patterns of human p38 and p38-2 were examined by Northern blot analysis of RNA isolated from various human tissues. p38 is widely expressed as a 4.3-kb mRNA in adult human tissues with highest levels in skeletal muscle (Fig. 2A). In contrast, p38-2 is expressed as a 4.5-kb RNA at very high levels in heart followed by skeletal muscle and at lower levels in various other tissues (Fig. 2B). We obtained an identical pattern of tissue distribution when we used as a probe a short oligonucleotide directed against the first intron of p38-2 (data not shown). This suggests that the poly(A)+ RNA preparation used for the Northern blot as well as the previously described cDNA library contained unspliced p38-2 mRNA species. All tissue samples expressed similar levels of beta -actin mRNA (data not shown).


Fig. 2. Tissue distribution of p38-2 and p38. The expression of human p38 (A) and human p38-2 (B) mRNA in selected adult human tissues was investigated by Northern blot analysis. The position of RNA size markers in kb is shown on the left.
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Substrate Specificity of p38-2

To determine whether p38-2 is a functional protein kinase, either a GST-p38-2 fusion protein produced in bacteria or HA-tagged p38-2 immunoprecipitated from non-stimulated transiently transfected 293 cells was employed in in vitro kinase assays with various substrates (Fig. 3, A and B). Recombinant p38-2 is active even without stimulation. The high basal level of activity may be due to strong autophosphorylation of the threonine and tyrosine in the TGY motif of the kinase domain as determined with phospho-specific antibodies (data not shown). p38-2 strongly phosphorylated the Ets family members Elk1 and Sap-1a, the bZIP protein ATF2, and very weakly c-Jun. In contrast, the NF-kappa B family members p65 and p50, Ikappa Balpha , C/EBPbeta , and estrogen receptor were not targeted by p38-2 kinase. Similar substrate specificity has been observed for p38 (23).


Fig. 3. Substrate specificity of p38-2. A, recombinant, purified GST-p38-2 (0.5 µg), or B, p38-2 (40 µg of cell extract) immunoprecipitated from 293 cells transfected with the indicated amounts of p38-2 expression vector was used in kinase reactions with 1 µg of purified recombinant substrates (GST, GST-Jun, GST-Elk1, NF-kappa B p65/Ikappa Balpha , NF-kappa B p50, C/EBPbeta , estrogen receptor (ER), GST-ATF2, GST-Sap-1a) as described under "Experimental Procedures." Reactions were separated by SDS-PAGE and visualized by autoradiography. The position of protein molecular mass markers in kDa is shown. C, increasing amounts of p38-2 expression vector were cotransfected with a luciferase reporter gene driven by two copies of the c-fos SRE (SRE2-tk80-luc) and expression vector for Sap-1a, Elk1, or the respective empty vector (pEV3S). Induction of relative luciferase activity by p38-2 is depicted.
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However, phosphorylation of a transcription factor does not necessarily lead to its activation. Therefore, we tested whether phosphorylation of the Ets transcription factor family members Elk1 and Sap-1a, which are involved in the regulation of the c-fos proto-oncogene via the serum response element (SRE) (38), leads to activation of c-fos SRE-dependent gene transcription. To that end, 293 cells were transfected with a luciferase reporter gene driven by two copies of the c-fos SRE, expression vectors for Elk1, Sap-1a, or the empty vector pEV3S and increasing amounts of p38-2 expression plasmid. As shown in Fig. 3C, Sap-1a dependent transcription was activated by p38-2 in a dose-dependent manner, whereas Elk1 could not activate transcription. A similar behavior has been observed with p38 (44). These results suggest that although the activity of p38-2 can be monitored in vitro with different substrates, this phosphorylation does not always lead to activation of the downstream target.

We next compared the phosphorylation of Sap-1a by p38-2 and p38 in more detail. To that end, GST-Sap-1a was phosphorylated in vitro by recombinant p38-2 and p38 and cleaved with chymotrypsin, and the resulting phosphopeptides were separated in two dimensions on cellulose thin layer plates (Fig. 4A). Although both MAPKs led to the generation of an identical phosphopeptide pattern, the intensity of the spots was different: whereas p38-2 phosphorylated peptides a-c approximately equally as well as peptides 1-5, p38 preferentially phosphorylated the peptides corresponding to spots 1-5. Mutational analysis has revealed that spots 1-5 are due to phosphorylation at serines 381 and 387 (44). These data suggest that serines 381 and 387 may be more critical for the activation of Sap-1a by p38 than by p38-2. To test this hypothesis, different potential MAPK phosphorylation sites in Sap-1a were mutated. The activity of the mutants was compared with that of the wild type molecule in transiently transfected 293 cells with the c-fos SRE luciferase reporter construct (Fig. 4B). Mutation of serines 381/387 reduced the transactivation potential of Sap-1a upon stimulation with both p38 and p38-2. But consistent with our in vitro phosphopeptide analysis, the serine 381/387 to alanine mutation had a more severe effect upon p38 stimulation than upon p38-2, relative luciferase activity was reduced to 10 and 30%, respectively. As a control we also tested Sap-1a alanine mutants at other sites previously shown to be targeted by MAPKs (44). Mutation of the MAPK sites at positions 420/425 did not affect the transactivation potential of Sap-1a, whereas mutation of threonines 361/366 to alanine affected Sap-1a activity to the same extent upon both p38-2 and p38MAPK stimulation. Combined mutation of all six aforementioned putative phosphorylation sites (6xA) resulted in an inactive Sap-1a molecule upon p38 and p38-2 stimulation.


Fig. 4. Two-dimensional phosphopeptide mapping. A, two-dimensional phosphopeptide mapping of GST-Sap-1a phosphorylated by recombinant p38-2 (left panel) or p38 (right panel). Spots a, b, and c have not been mapped. Spots 1-5 are due to phosphorylation at serines 381 and 387 of Sap-1a. B, 293 cells were transiently transfected with SRE2-tk80-luc, expression vectors for Sap-1a (wild type and mutants as indicated), and expression vectors for p38 or p38-2. Luciferase activity obtained with wild type Sap-1a was assigned 100%.
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Kinetic Characterization of p38 and p38-2

Interestingly, p38-2 expressed in bacteria or in mammalian cells is always more active than p38. A more detailed titration analysis of recombinant GST-p38-2 and GST-p38 revealed about 100 times higher kinase activity of p38-2 toward the substrate ATF2 (data not shown). This prompted us to carry out a kinetic analysis of both kinases using ATF2 as substrate.

The kinetic mechanism of GST-p38-2 was investigated by varying the concentrations of both ATP and GST-ATF2 in a single experiment. Both double-reciprocal plots of 1/v versus 1/[GST-ATF2] at fixed ATP concentrations (Fig. 5A) and 1/v versus 1/[ATP] at fixed GST-ATF2 concentrations (Fig. 5B) exhibited an intersecting pattern consistent with a sequential reaction mechanism. A sequential mechanism would proceed through a ternary complex of p38-2, ATP, and GST-ATF2 before a chemical step. Clearly, the double-reciprocal plots do not have a family of parallel lines, the hallmark of a ping-pong type mechanism. Initial velocity data were subjected to a nonlinear, least squares fit to the general rate equation of a Bi Bi mechanism excluding product inhibition terms (reactions had less than 10% of the ATP turned over) (see Table I) (57, 58). Note that the Ki, ATP ("inhibition constant" for ATP) and Ki, GST-ATF2 ("inhibition constant" for GST-ATF2) values are similar to the Km values, which would be expected for a kinetic mechanism that is not ordered. This similarity is consistent with a rapid equilibrium, random mechanism, but it is not proof of a kinetic mechanism.


Fig. 5. Kinetic analysis of p38-2 and p38. A, 1/V as a function of either GST-ATF2 (0.313, 0.625, 1.25, 2.50, and 5.0 µM) concentration at fixed ATP concentrations: 0.05 µM (black-square), 0.5 µM (bullet ), 2.5 µM (black-triangle), and 5.0 µM (black-diamond ). B, 1/V as a function of ATP concentration (0.05, 0.5, 2.5, 5.0 µM) at fixed GST-ATF2 concentrations: 0.313 µM (black-square), 0.625 µM (bullet ), 1.25 µM (black-triangle), 2.50 µM (black-diamond ), 5.0 µM (square ). The velocity data was fit to the equation for a sequential Bi Bi mechanism by a nonlinear least squares method to obtain the kinetic parameters. C, kinetic analysis of the relative processing of GST-ATF2 by p38 (bullet ) and p38-2 (black-square). The Km values of p38-2 and p38 were determined to be 3.9 ± 0.3 and 9.2 ± 1.6, respectively. The kcat values of p38-2 and p38 were determined to be 14.2 ± 0.6 and 0.078 ± 0.011 min-1, respectively. GST-ATF2 concentration was varied from 0.156 to 2.5 µM, whereas the concentrations of p38-2 and p38 are 18 and 600 nM, respectively.
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Table I. Kinetic parameters of p38-2

Kinetic parameters of p38-2 are displayed as a function of both [GST-ATF2] and [ATP]. [GST-ATF2] was varied from 0.313 to 5.0 µM and [ATP] was varied from 0.05 to 5 µM. The p38-2 concentration was 12.1 nM.

Substrate Kinetic constants from two-substrate kinetics
Km kcat Ki,GST-ATF2 Ki,ATP

µM min-1 µM µM
GST-ATF2 1.6  ± 0.4 10.8  ± 2.6 2.5  ± 0.4
ATP 5.8  ± 1.8 9.3  ± 3.0

Equal amounts of GST-p38 and GST-p38-2 proteins expressed in bacteria and processed to similar purity were employed for kinase activity studies. Comparison of GST-p38 and GST-p38-2 kinase activity at a fixed concentration of ATP (15 µM) and variable GST-ATF2 concentrations revealed that there was a modest but significant difference in the apparent K*m, GST-ATF2 values: 3.9 ± 0.3 µM for p38-2 and 9.2 ± 1.6 µM for p38 (Fig. 5C). This indicates an approximate 2-fold higher affinity of p38-2 for its substrate GST-ATF2. The major difference in the kinetic parameters resides in the k*cat values: 14.3 ± 0.6 min-1 for p38-2 and 0.079 ± 0.011 min-1 for p38. The specific activities of p38 and p38-2 with a saturating level of GST-ATF2 and 15 µM ATP were calculated to be 1.2 and 315 nmol·min-1mg-1, respectively. In summary these studies revealed a marginal higher substrate affinity and a more than 180-fold higher catalytic activity of p38-2 compared with p38.

p38-2 Is a Stress-activated Kinase

Next, we examined whether p38-2 like p38 is activated by stress-inducing signals. COS cells were transiently transfected with an expression vector encoding epitope-tagged p38-2 (3xHA-p38-2). Immune complex kinase assays with ATF2 as substrate demonstrated an up to 4-fold increase in p38-2 kinase activity when cells were treated with interleukin-1beta , NaCl, UV light, or anisomycin (Fig. 6, lanes 5-13). Stimulators of the ERK cascade including phorbol 12-myristate 13-acetate and growth factors did not activate p38-2. These results indicate that p38-2 is a member of the family of stress-activated kinases.


Fig. 6. Stimulators of p38-2 in vivo. COS cells were transiently transfected with epitope-tagged p38-2 and cotransfected with expression vectors for constitutive active MEK6 (MEK6(DD)), MEKK1, and TAK1Delta N (lanes 3 and 4) or treated for 45 min with phorbol 12-myristate 13-acetate (50 ng/ml; Sigma), epidermal growth factor (50 ng/ml; Life Technologies, Inc.), nerve growth factor (50 ng/ml; Life Technologies, Inc.), TGFbeta (20 ng/ml; Life Technologies, Inc.), interleukin-1beta (10 ng/ml; R&D Systems), tumor necrosis factor-alpha (10 ng/ml; R&D Systems), NaCl (200 mM; Sigma), UV light (254 nm; 120 J/m2), anisomycin (50 ng/ml; Sigma) (lanes 5-13). Cell lysates were used in an immune complex kinase assay with GST-ATF2 substrate as described under "Experimental Procedures." The position of protein molecular mass markers in kDa is shown on the left. The presence of equal amounts of p38-2 in all kinase reactions was confirmed by Western blot analysis (data not shown). The relative phosphorylation of GST-ATF2 substrate in lanes 1-13 is 1.0, 5.5, 2.2, 4.2, 1.4, 0.6, 0.6, 1.1, 3.3, 0.6, 3.2, 2.5, and 4.0.
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We were then interested in identifying components of the upstream activator cascade. MEK6 and TAK1 have been described to activate p38 (22, 28, 29, 32). Cotransfection experiments in COS cells yielded similar results for p38-2. MEK6 increased the kinase activity of p38-2 by 5.5-fold, and TAK1 increased p38-2 activity by 4.2-fold (Fig. 6, lanes 2 and 4). In contrast, MEKK1, a specific activator of JNKK, activated p38-2 2.2-fold only (Fig. 6, lane 3). To exclude that changes of p38-2 kinase activity are caused by different levels of expression of p38-2 in response to treatment of cells with stimulators, we performed Western blot analysis with an anti-HA antibody. p38-2 was present at equal levels in all cell lysates (data not shown).

In a similar experiment we analyzed the effect of MEK6 and TAK1 on p38-2 in 293 cells. p38-2 kinase activity was measured in an immune complex kinase assay with Elk1 as a substrate (Fig. 7A, upper panel). TAK1 wild type increased the phosphorylation of Elk1 3.6-fold above the level obtained with a kinase-defective TAK1-K63W mutant (33) (Fig. 7A, compare lanes 4 and 5). TAK1Delta N, an N-terminally truncated version of TAK1 missing the first 22 amino acids, was slightly less active (2.2-fold). No phosphorylation of Elk1 was detected in the absence of p38-2 (Fig. 7A, lanes 1-3). Western blots confirmed that the expression of TAK1 did not change p38-2 protein levels (Fig. 7A, lower panel). In a parallel study we investigated the effect of MEK6 and TAK1 with the SRE-luciferase reporter system. Confirming the in vitro kinase studies shown in Fig. 6, wild type MEK6 and to a greater extent the constitutive active mutant MEK6(DD) increased the effect of p38-2 on the SRE-luciferase reporter (Fig. 7B). Additionally, TAK1 and TAK1Delta N but not TAK1-K63W stimulated p38-2. Since a detailed analysis of the TAK1 MAPKKK has not been performed, we investigated which MAPK pathways were activated by TAK1. To that end, TAK1 was coexpressed with HA-tagged ERK-1, JNK-1, and p38-2 in 293 cells, and the activity of the different MAPKs was assessed after immunoprecipitation in an in vitro kinase assay (Fig. 7C). Similar to p38-2, ERK-1 was ~3-fold stimulated by TAK1, but JNK-1 was more than 15-fold stimulated. Thus, TAK1 may activate all three known MAPK pathways in mammals but appears to be most efficient as a MAPKKK in the JNK pathway.


Fig. 7. MEK6 and TAK1 activate p38-2 in vivo. A, HA-tagged TAK1 or mutants thereof were transiently produced in 293 cells with (lanes 4-6) or without (lanes 1-3) HA-tagged p38-2. After immunoprecipitation with an anti-HA antibody, in vitro kinase reactions were performed with GST-Elk1 as a substrate (upper panel). The lower panel shows a corresponding Western blot revealing the HA-tagged proteins. B, the indicated versions of MEK6 or TAK1 or the empty expression vector SRalpha 3 (-) were transfected into 293 cells in the presence of SRalpha 3 (-) or p38-2 expression vector. Stimulation of the SRE2-tk80-luc reporter by Sap-1a was measured in a luciferase assay. C, HA-tagged p38-2, JNK1, or ERK1 were transiently expressed in 293 cells in the absence or presence of HA-tagged TAK1. After immunoprecipitation with an anti-HA antibody, in vitro kinase reactions were performed with GST-Elk1 as a substrate (upper panel). The lower panel shows a corresponding Western blot revealing the HA-tagged proteins.
[View Larger Version of this Image (25K GIF file)]

Pyridinyl Imidazole Inhibits p38 and p38-2

A specific inhibitor of p38 with no effect on ERK and JNK was described by Lee and co-workers (12). SB203580, a pyridinyl imidazole derivative, efficiently blocks the kinase activity of p38 and also strongly diminishes production of several cytokines (21). Therefore, we were interested to determine whether this compound also interferes with p38-2 kinase activity using ATF2 as substrate. As shown in Fig. 8A, SB203580 blocked phosphorylation of ATF2 by p38 as well as by p38-2 with an IC50 of around 1 µM for both kinases.


Fig. 8. Inhibition of p38 and p38-2. A, recombinant, purified GST-p38 and GST-p38-2 were preincubated for 30 min with increasing concentrations of SB203580 as indicated and then tested in a kinase reaction with 1 µg of purified recombinant GST-ATF2 as described under "Experimental Procedures." Reactions were separated by SDS-PAGE and visualized by autoradiography. Phosphate incorporation was quantified with a PhosphorImager (Molecular Dynamics), and the levels in the absence of were SB203580 set to 100%. B, HeLa cells were transiently transfected with 5xGAL4-LUC, GAL4-ATF2, the empty expression vector SRalpha 3, or expression vectors for MEK6(DD) or MEKK1. Increasing concentrations of SB203580 were added 20 h before measuring luciferase activity.
[View Larger Version of this Image (23K GIF file)]

To evaluate the specificity of this compound in vivo, we employed a transcription factor based assay that depends on the phosphorylation of ATF2 at positions 69 and 71. Since ATF2 is a target for the JNK and p38 cascades, we used rather selective upstream activators for each cascade, constitutively active MEKK1 and MEK6, respectively (29). As shown in Fig. 8B, MEKK1 as well as MEK6(DD) increased the activity of GAL4-ATF2 about 8-fold. In accordance with our in vitro data, addition of SB203580 to the cells decreased stimulation of ATF2 activity by MEK6 but not by MEKK1 in a dose-dependent manner. SB203580 had no effect on the expression of MEK6 as confirmed by Western blot analysis (data not shown).


DISCUSSION

In this report we describe the cloning and features of a novel member of the MAPK family, p38-2. This protein kinase shares 73% amino acid identity and 86% similarity with mammalian p38 and especially displays the same dual phosphorylation motif TGY, which groups p38-2 into the p38MAPK subfamily. Interestingly, p38-2 exists in at least three isoforms due to unspliced mRNA species that contain introns providing in-frame stop codons. The mRNAs with introns were found in several independent RNA preparations. Furthermore, the signal strength of Northern blot analyses with an intron 1 probe was similar in intensity to that of a p38-2 cDNA probe (data not shown). Reverse transcriptase-PCR confirmed that in some cell lines up to 50% of the p38-2 mRNA has introns (data not shown). This suggests that mRNA species with introns are quite prominent and therefore are not likely to be caused by a contamination with nuclear RNA. The tissue distribution of isoform 1 mRNA is identical to the intron-less mRNA (data not shown). Assuming similar transcription and protein stability, the wild type and truncated ratios (50:25:25) could yield significant amounts of each isoform. We are currently investigating the effect of p38-2 isoforms on the MEK6/p38-2 signaling cascade. Since isoform 1 as well as 2 lack the TGY phosphorylation motif, they are unlikely to perform an active part in signaling cascades. Rather, they may interfere with the regulation of full-length p38-2 by competing for binding to activating MAPKKs such as MEK6.

While this work was under preparation a nearly identical protein kinase, p38beta (GenbankTM accession number U53442), was identified by Jiang and co-workers (55). This protein kinase has three substitutions and an insert of eight amino acids between amino acid positions 119 and 123. Thus it may represent a third isoform of the same gene or is a new family member. Therefore, the p38 subgroup of MAPK consists of p38 (also known as CSBP, RK), p38-2, p38beta , Mxi2, and ERK6 (also known as SAPK3).

A comparison of p38 and p38-2 mRNA expression revealed that both protein kinases are rather widely expressed. However, both kinases displayed a great variance in the degree of expression depending on the tissue analyzed, and also p38-2 and p38 were differently expressed. Expression levels in heart and testis are significantly higher for p38-2, and expression levels in placenta and ovary are significantly lower. The expression pattern of Mxi2 is similar to that of p38 (25). In contrast, ERK6 has been described to be restricted to skeletal muscle (56), which is puzzling in view of the wide tissue distribution of its rat homologue SAPK3 as well as human SAPK3 (59, 60).

Similarities between p38-2 and p38 prompted us to investigate their substrate specificity. p38-2 as well as p38 efficiently phosphorylate ATF2, Elk1, and Sap-1a. However, c-Jun, the preferred substrate for JNK, is only weakly phosphorylated by p38-2. This suggests that the substrate selectivity of p38-2 is very similar to p38 although we cannot exclude that there are other substrates that distinguish between these two MAPK. The substrate specificity of SAPK3 overlaps but is distinct from p38 and p38-2. SAPK3 does not phosphorylate MAPKAP K2 (59). Strikingly, the site preference for individual phosphorylation sites within one target protein can differ, as shown with Sap-1a. Phosphopeptide analyses revealed that p38 as well as p38-2 have overlapping phosphorylation sites in Sap-1a. However, p38 prefers serines 381/387 in Sap-1a relative to p38-2. Consequently, mutation of serines 381/387 affected activation of Sap-1a-mediated transcription by p38 in vivo significantly more than that by p38-2. The phosphopeptides a-c that are strongly recognized by p38-2 have not been mapped. It would be interesting to compare these two phosphopeptide patterns with the pattern created by SAPK3, which also has been described to phosphorylate Sap-1a. These studies open the question how does differential phosphorylation of a substrate affect its activity? Would it be possible to design inhibitors that block phosphorylation of a substrate by one kinase but not by the other? Do MAPK differentially phosphorylate their substrates dependent on the stimulator used?

In addition, we found that phosphorylation of Elk1 by p38-2, in contrast to Sap-1a and ATF2, does not lead to an increase in Elk-1-mediated transcription, a phenomenon that has also been observed with p38 (44). This suggests that Elk1 is not phosphorylated at sites critical for its transcriptional activity and stresses the fact that phosphorylation of a transcription factor does not necessarily lead to its activation.

In addition to the differential phosphorylation of Sap-1a by p38 and p38-2, we observed that ATF2 is a much better substrate for p38-2 than p38. p38beta is also more active than p38 using GST-ATF2 as substrate (55). Investigation of the kinetic mechanism of p38 and p38-2 using ATF2 as substrate revealed a modest 2-fold higher substrate affinity and more than 180-fold higher catalytic activity of p38-2. The concentration of kinase used in our experiments was 18-600 nM, which is the physiological range of MAPK family members in the cell (30-2800 nM) (61). As the kcat values for p38 were less than 5 min-1, which is considered low and problematic (58), p38 appears to be a very inefficient kinase, and it is possible that its true substrate has yet to be identified. This effect could be caused by a less efficient turnover of GST-ATF2 by p38 or a lower fraction of active p38 in the bacterial fusion protein preparation. However, the latter is unlikely since several independent preparations of bacterial GST-p38 and GST-p38-2 proteins yielded similar results. Furthermore, Coomassie staining of purified GST-p38 and GST-p38-2 showed similar yield and purity (data not shown). Although our data likely reflect true differences in the catalytic activity of GST-p38 and GST-p38-2, we cannot exclude that upon activation in vivo by MAPKK, the catalytic activities of p38 and p38-2 may not be so dramatically different. However, preliminary data demonstrated that p38-2 activated in vivo by cotransfected, constitutively active MEK6 is about 30 times more active than a similarly activated p38 (data not shown). We also discovered that p38-2 but not p38 prepared in bacteria is phosphorylated. It is therefore possible that p38-2 activates itself by autophosphorylation. Autophosphorylation has been described for many MAPK. More work is necessary to distinguish between autophosphorylation and phosphorylation by a bacterial kinase. Generation of p38-2 mutants of the ATP binding site or the phospho-acceptor sites should help to answer these questions in future studies.

Consistent with its classification as a member of the p38MAPK subfamily, p38-2 was activated in vivo by stress-inducing signals. Osmotic shock, UV light, anisomycin, and interleukin-1beta strongly increased p38-2 activity, whereas TGFbeta and tumor necrosis factor-alpha were more modest activators. This profile of stimulation of p38-2 is reminiscent of p38. The upstream protein kinase MEK6 is a very efficient activator of p38 in vivo (22, 29). We show here that MEK6(DD), a constitutively active mutant of MEK6, also increased p38-2 activity in vivo. Furthermore, we and others (27, 29) have previously shown that MEKK1, an activator of JNKK, can cross-talk to the MKK3/MEK6 cascade, but a careful titration analysis showed that much higher amounts of MEKK1 are necessary for activation of MEK6 compared with JNKK (29). In support of these observations MEKK1 was found to be significantly less active on p38-2 than MEK6. In summary these and other studies showed that at least four members of the p38 family (p38, p38-2, p38beta , and ERK6) are activated by MEK6.

TAK1 has also been described to activate MEK6 (32). Surprisingly, a more detailed analysis of the effect of TAK1 and the N-terminal truncation TAK1Delta N on p38-2 activity in vitro and in vivo on a SRE reporter did not reveal a significant higher activity of TAK1Delta N. This is in contrast to a previous report demonstrating that the wild type TAK1 molecule is inactive in mammalian cells and that the TAK1Delta N deletion, missing the first 22 amino acids, is constitutively active (33). Interestingly, a side-by-side comparison of the activation of members from three major MAPK cascades, p38-2, JNK, and ERK-1, revealed that JNK is by far the best target for TAK1. Our findings are in agreement with the suggestion that JNK is a downstream target for TAK1 (33). Many more studies will be needed to sort out which of the described kinases from the MAPKKK level (DLK, MEKK1, MLK3, MUK, Pak1, TAK1, and Tpl2) leads to physiological activation of MEK6 and MKK3.

Lee and co-workers (50) previously showed that p38 is inhibited by the pyridinyl imidazole derivative SB203580. This compound is highly selective for p38 and does not interfere with closely related kinases such as JNK and ERK. Our studies showed that p38-2 is also a target for this inhibitor with an IC50 identical to p38. Studies by Jiang et al. (55) showed that an analogue of SB203580, SB202190, inhibits p38beta equally well. Interestingly, SAPK3, the rat homologue of ERK6, is not inhibited by SB203580 at concentrations up to 100 µM (59). SB203580 also interferes with p38/p38-2 activity in vivo (Fig. 8). Therefore, some of the biological effects attributed to p38 may be mediated by p38-2 and p38beta . The selective activation of GAL4-ATF2 by low concentrations of MEKK1 is likely to affect only the activation of the JNKKright-arrowJNKright-arrowATF2 cascade. These data support our conclusion that MEKK1 is the physiological activator of the JNK but not the p38 cascade. On the other hand, activation of GAL4-ATF2 by MEK6 via p38/p38-2 was efficiently blocked by SB203580. Further studies in vivo with this compound are required to unravel the redundancy as well as specificity of these kinases. All p38 family members phosphorylate a number of proteins in vitro. However, not all phosphorylation events lead to an increase in transcriptional activity of the substrates. Furthermore, substrate specificity in vitro may vary in vivo.


FOOTNOTES

*   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.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U92268.


§   To whom correspondence should be addressed: Signal Pharmaceuticals Inc., 5555 Oberlin Dr., San Diego, CA 92121. Tel.: 619-558-7500; Fax: 619-558-7513; E-mail: bstein{at}signalpharm.com.
par    Supported by a scholarship from the Deutsche Forschungsgemeinschaft.
1   The abbreviations used are: MAPKs, mitogen-activated protein kinases; MAPKK, MAP kinase kinase; MAPKKK, MAP kinase kinase kinase; MAPKAP, MAP kinase-activated protein; CSBP, cytokine-suppressive anti-inflammatory drug binding protein; JNK, c-Jun N-terminal kinase; JNKK, JNK kinase; MEKK, MAPK/ERK kinase kinase; ERK, extracellular signal-regulated kinase; TAK1, TGFbeta -activated kinase 1; EST, expressed sequence tags; NCBI, National Center for Biotechnology Information; HA, hemagglutinin; PCR, polymerase chain reaction; GST, glutathione S-transferase; kb, kilobase pair(s); bp base pair(s); PAGE, polyacrylamide gel electrophoresis; SRE, serum-response element; LUC, luciferase; TGFbeta , transforming growth factor beta .
2   The intron 1 sequence is GTGAGCGGCGGGCGGGCGAGGCAGCGGGAGCGCGTTCGCGGTGGGGCGGTGGGGCCCTGTCCTGACCCCCTGACCCCGCCCCAG.
3   The intron 2 sequence is GTAGGTGCGACCGCAGGGTGAGGGTCGGGTCCAGCAGGGCTCCGTCCCAGCCTCCTGTGCTCACGCTCCGCGTGACCTGCAG.

ACKNOWLEDGEMENTS

We gratefully acknowledge the technical assistance of Kimi Ueda. We thank K. Matsumoto and H. Shibuya for providing valuable reagents and the Medicinal Chemistry Department at Signal Pharmaceuticals for preparing SB203580. We also thank D. Anderson for support and encouragement.


REFERENCES

  1. Cobb, M. H., Boulton, T. G., and Robbins, D. J. (1991) Cell Regul. 2, 965-978 [Medline] [Order article via Infotrieve]
  2. Hunter, T., and Karin, M. (1992) Cell 70, 375-387 [Medline] [Order article via Infotrieve]
  3. Davis, R. J. (1994) Trends Biochem. 19, 470-473 [CrossRef][Medline] [Order article via Infotrieve]
  4. Cano, E., and Mahadevan, L. C. (1995) Trends Biochem. 20, 117-122 [CrossRef][Medline] [Order article via Infotrieve]
  5. Hunter, T. (1995) Cell 80, 225-236 [Medline] [Order article via Infotrieve]
  6. Herskowitz, I. (1995) Cell 80, 187-197 [Medline] [Order article via Infotrieve]
  7. Seger, R., and Krebs, E. G. (1995) FASEB J. 9, 726-735 [Abstract/Free Full Text]
  8. Waskiewicz, A. J., and Cooper, J. A. (1995) Curr. Opin. Cell Biol. 7, 798-805 [CrossRef][Medline] [Order article via Infotrieve]
  9. Stein, B., and Anderson, D. (1996) in Annual Reports in Medicinal Chemistry (Bristol, J. A., ed), Vol. 31, pp. 289-298, Academic Press, San Diego
  10. Han, J., Lee, J.-D., Bibbs, L., and Ulevitch, R. J. (1994) Science 265, 808-811 [Medline] [Order article via Infotrieve]
  11. Rouse, J., Cohen, P., Trigon, S., Morange, M., Alonso-Llamazares, A., Zamanillo, D., Hunt, T., and Nebreda, A. R. (1994) Cell 78, 1027-1037 [Medline] [Order article via Infotrieve]
  12. Lee, J. C., Laydon, J. T., McDonnell, P. C., Gallagher, T. F., Kumar, S., Green, D., McNulty, D., Blumenthal, M. J., Heys, J. R., Landvatter, S. W., Strickler, J. E., McLaughlin, M. M., Siemens, I. R., Fisher, S. M., Livi, G. P., White, J. R., Adams, J. L., and Young, P. R. (1994) Nature 372, 739-746 [CrossRef][Medline] [Order article via Infotrieve]
  13. Sen, J., Kapeller, R., Fragoso, R., Sen, R., Zon, L. I., and Burakoff, S. J. (1996) J. Immunol. 156, 4535-4538 [Abstract/Free Full Text]
  14. Tan, Y., Rouse, J., Zhang, A., Cariati, S., Cohen, P., and Comb, M. J. (1996) EMBO J. 15, 4629-4642 [Abstract]
  15. Tao, J., Sanghera, J. S., Pelech, S. L., Wong, G., and Levy, J. G. (1996) J. Biol. Chem. 271, 27107-27115 [Abstract/Free Full Text]
  16. Wang, X. Z., and Ron, D. (1996) Science 272, 1347-1349 [Abstract]
  17. Freshney, N. W., Rawlinson, L., Guesdon, F., Jones, E., Cowley, S., Hsuan, J., and Saklatvala, J. (1994) Cell 78, 1039-1049 [Medline] [Order article via Infotrieve]
  18. Raingeaud, J., Gupta, S., Rogers, J. S., Dickens, M., Han, J., Ulevitch, R. J., and Davis, R. J. (1995) J. Biol. Chem. 270, 7420-7426 [Abstract/Free Full Text]
  19. Kramer, R. M., Roberts, E. F., Strifler, B. A., and Johnstone, E. M. (1995) J. Biol. Chem. 270, 27395-27398 [Abstract/Free Full Text]
  20. Saklatvala, J., Rawlinson, L., Waller, R. J., Sarsfield, S., Lee, J. C., Morton, L. F., Barnes, M. J., and Farndale, R. W. (1996) J. Biol. Chem. 271, 6586-6589 [Abstract/Free Full Text]
  21. Beyaert, R., Cuenda, A., Berghe, W. V., Plaisance, S., Lee, J. C., Haegeman, G., Cohen, P., and Fiers, W. (1996) EMBO J. 15, 1914-1923 [Abstract]
  22. Raingeaud, J., Whitmarsh, A. J., Barrett, T., Dérijard, B., and Davis, R. J. (1996) Mol. Cell. Biol. 16, 1247-1255 [Abstract]
  23. Han, J., Richter, B., Li, Z., Kravchenko, V., and Ulevitch, R. J. (1995) Biochim. Biophys. Acta 1265, 224-227 [Medline] [Order article via Infotrieve]
  24. McLaughlin, M. M., Kumar, S., McDonnell, P. C., Van Horn, S., Lee, J. C., Livi, G. P., and Young, P. R. (1996) J. Biol. Chem. 271, 8488-8492 [Abstract/Free Full Text]
  25. Zervos, A. S., Faccio, L., Gatto, J. P., Kyriakis, J. M., and Brent, R. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 10531-10534 [Abstract]
  26. Dérijard, B., Raingeaud, J., Barrett, T., Wu, I.-H., Han, J., Ulevitch, R. J., and Davis, R. J. (1995) Science 267, 682-685 [Medline] [Order article via Infotrieve]
  27. Lin, A., Minden, A., Martinetto, H., Claret, F.-X., Lange-Carter, C., Mercurio, F., Johnson, G. L., and Karin, M. (1995) Science 268, 286-290 [Medline] [Order article via Infotrieve]
  28. Han, J., Lee, J.-D., Jiang, Y., Li, Z., Feng, L., and Ulevitch, R. J. (1996) J. Biol. Chem. 271, 2886-2891 [Abstract/Free Full Text]
  29. Stein, B., Brady, H., Yang, M. X., Young, D. B., and Barbosa, M. S. (1996) J. Biol. Chem. 271, 11427-11433 [Abstract/Free Full Text]
  30. Zhang, S., Han, J., Sells, M. A., Chernoff, J., Knaus, U. G., Ulevitch, R. J., and Bokoch, G. M. (1995) J. Biol. Chem. 270, 23934-23936 [Abstract/Free Full Text]
  31. Fan, G., Merritt, S. E., Kortenjann, M., Shaw, P. E., and Holzman, L. B. (1996) J. Biol. Chem. 271, 24788-24793 [Abstract/Free Full Text]
  32. Moriguchi, T., Kuroyanagi, N., Yamaguchi, K., Gotoh, Y., Irie, K., Kano, T., Shirakabe, K., Muro, Y., Shibuya, H., Matsumoto, K., Nishida, E., and Hagiwara, M. (1996) J. Biol. Chem. 271, 13675-13679 [Abstract/Free Full Text]
  33. Yamaguchi, K., Shirakabe, K., Shibuya, H., Irie, K., Oishi, I., Ueno, N., Taniguchi, T., Nishida, E., and Matsumoto, K. (1995) Science 270, 2008-2011 [Abstract]
  34. Guan, K. L., and Dixon, J. E. (1991) Anal. Biochem. 192, 262-267 [Medline] [Order article via Infotrieve]
  35. Dérijard, B., Hibi, M., Wu, I.-H., Barrett, T., Su, B., Deng, T., Karin, M., and Davis, R. J. (1994) Cell 76, 1025-1037 [Medline] [Order article via Infotrieve]
  36. Boulton, T. G., and Cobb, M. H. (1991) Cell Regul. 2, 357-371 [Medline] [Order article via Infotrieve]
  37. Minden, A., Lin, A., McMahon, M., Lange-Carter, C., Dérijard, B., Davis, R. J., Johnson, G. L., and Karin, M. (1994) Science 266, 1719-1722 [Medline] [Order article via Infotrieve]
  38. Janknecht, R., Ernst, W. H., Pingoud, V., and Nordheim, A. (1993) EMBO J. 12, 5097-5104 [Abstract]
  39. Janknecht, R., Ernst, W. H., and Nordheim, A. (1995) Oncogene 10, 1209-1216 [Medline] [Order article via Infotrieve]
  40. Robbins, D. J., Zhen, E., Owaki, H., Vanderbilt, C. A., Ebert, D., Geppert, T. D., and Cobb, M. H. (1993) J. Biol. Chem. 268, 5097-5106 [Abstract/Free Full Text]
  41. Hibi, M., Lin, A., Smeal, T., Minden, A., and Karin, M. (1993) Genes Dev. 7, 2135-2148 [Abstract]
  42. Gupta, S., Campbell, D., Dérijard, B., and Davis, R. J. (1995) Science 267, 389-393 [Medline] [Order article via Infotrieve]
  43. Marais, R., Wynne, J., and Treisman, R. (1993) Cell 73, 381-393 [Medline] [Order article via Infotrieve]
  44. Janknecht, R., and Hunter, T. (1997) EMBO J. 16, 1620-1627 [Abstract/Free Full Text]
  45. Stein, B., Baldwin, A. S., Jr., Ballard, D. W., Greene, W. C., Angel, P., and Herrlich, P. (1993) EMBO J. 12, 3879-3891 [Abstract]
  46. Stein, B., Cogswell, P. C., and Baldwin, A. S., Jr. (1993) Mol. Cell. Biol. 13, 3964-3974 [Abstract]
  47. Stein, B., and Yang, M. X. (1995) Mol. Cell. Biol. 15, 4971-4979 [Abstract]
  48. Matthias, P., Muller, M. M., Schreiber, E., Rusconi, S., and Schaffner, W. (1989) Nucleic Acids Res. 17, 6418 [Medline] [Order article via Infotrieve]
  49. Livingstone, C., Patel, G., and Jones, N. (1995) EMBO J. 14, 1785-1797 [Abstract]
  50. Cuenda, A., Rouse, J., Doza, Y. N., Meier, R., Cohen, P., Gallagher, T. F., Young, P. R., and Lee, J. C. (1995) FEBS Lett. 364, 229-233 [CrossRef][Medline] [Order article via Infotrieve]
  51. Graham, F. L., and van der Eb, A. J. (1973) Virology 52, 456-467 [Medline] [Order article via Infotrieve]
  52. Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 [CrossRef][Medline] [Order article via Infotrieve]
  53. van der Geer, P., Luo, K., Sefton, B. M., and Hunter, T. (1994) in Cell Biology: A Laboratory Handbook (Celis, J. E., ed), Vol. 3, pp. 422-448, Academic Press, San Diego
  54. Cleland, W. W. (1979) Methods Enzymol. 63, 103-138 [Medline] [Order article via Infotrieve]
  55. Jiang, Y., Chen, C., Li, Z., Guo, W., Gegner, J. A., Lin, S., and Han, J. (1996) J. Biol. Chem. 271, 17920-17926 [Abstract/Free Full Text]
  56. Lechner, C., Zahalka, M. A., Giot, J.-F., Møller, N. P. H., and Ullrich, A. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 4355-4359 [Abstract/Free Full Text]
  57. Segal, I. H. (1975) Enzyme Kinetics: Behavior and Analysis of Rapid Equilibrium and Steady-state Enzyme Systems, pp. 643-646, John Wiley & Sons, Inc., New York
  58. Cole, P. A., Burn, P., Takacs, B., and Walsh, C. T. (1994) J. Biol. Chem. 269, 30880-30887 [Abstract/Free Full Text]
  59. Cuenda, A., Cohen, P., Buée-Scherrer, V., and Goedert, M. (1997) EMBO J. 16, 295-305 [Abstract/Free Full Text]
  60. Mertens, S., Craxton, M., and Goedert, M. (1996) FEBS Lett. 383, 273-276 [CrossRef][Medline] [Order article via Infotrieve]
  61. Ferrell, J. E., Jr. (1996) Trends Biochem. 21, 460-466 [CrossRef][Medline] [Order article via Infotrieve]

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