Epidermal Growth Factor Induction of the c-jun Promoter by a Rac Pathway

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Clarke, N.
	Articles by Prywes, R.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Clarke, N.
	Articles by Prywes, R.

Previous Article | Next Article

Mol Cell Biol, February 1998, p. 1065-1073, Vol. 18, No. 2
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Epidermal Growth Factor Induction of the c-jun Promoter by a Rac Pathway

Nicole Clarke,¹ Natalia Arenzana,¹ Tsonwin Hai,² Audrey Minden,¹ and Ron Prywes¹^,^*

Department of Biological Sciences, Columbia University, New York, New York 10027,¹ and Ohio State Biochemistry Program and Department of Medical Biochemistry and Neurobiotechnology Center, Ohio State University, Columbus, Ohio 43210²

Received 1 August 1997/Returned for modification 17 September 1997/Accepted 31 October 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

The c-jun proto-oncogene encodes a transcription factor which is activated by mitogens both transcriptionally and by phosphorylationby Jun N-terminal kinase (JNK). We have investigated the cellularsignalling pathways involved in epidermal growth factor (EGF)induction of the c-jun promoter. We find that two sequence elements,which bind ATF1 and MEF2D transcription factors, are requiredin HeLa cells, although they are not sufficient for maximal induction.Activated forms of Ras, RacI, Cdc42Hs, and MEKK increased expressionof the c-jun promoter, while dominant negative forms of Ras, RacI,and MEK kinase (MEKK) inhibited EGF induction. These and previouslypublished results suggest that EGF activates the c-jun promoterby a Ras-to-Rac-to-MEKK pathway. This pathway is similar to thatused for posttranslational activation of c-jun by JNK.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

The proto-oncogene c-jun is activated in mitogen-treated cells by two mechanisms. The first is phosphorylation of the N-terminalregion of the c-Jun protein by Jun N-terminal kinase (JNK) (23,62). Activation of JNK is mediated by activation of a signallingpathway including the small GTPase Rac and protein kinases MEKkinase (MEKK) and JNKK (also known as MKK4 and SEK) (reviewedin references 30 and 62). The second mechanism for c-jun activationis induction of c-jun transcription (34, 52, 55). c-junis a cellular immediate-early gene whose transcription is increasedrapidly in response to external stimuli such as growth factors.This increase does not require new protein synthesis and thusshould be due to a limited number of posttranslational events(34, 52).

c-jun is rapidly induced in cultured cells in response to certain stimuli such as epidermal growth factor (EGF), serum, 12-O-tetradecanoylphorbol-13-acetate (TPA), nerve growth factor, and UV (4, 12,34, 52, 55, 65). It is as yet unclear whether these agentsuse a common pathway. Induction of c-jun is important for cellcycle progression since antibodies to the c-jun product blockedprogression of NIH 3T3 cells through the cell cycle (31). Thec-jun gene encodes a component of the AP1 transcription factor,which binds DNA elements termed TPA-responsive elements or AP1sites (reviewed in reference 3). Earlier studies showed thatan AP1-like element in the c-jun promoter mediated positive autoregulationof the c-jun gene (2).

We have previously shown that a site situated at $-$ 59 of the c-jun promoter and, to a lesser extent, the AP1-like site at $-$ 72are important for serum and EGF induction of the c-jun promoter(20). This latter site is bound by AP1 and ATF family members,both basic-leucine zipper DNA binding families, but it has beenunclear which factors bind this site in cells (2, 22, 58).The $-$ 59 site in the c-jun promoter binds members of the MEF2 familyof proteins, which include MEF2A, -B, -C, and -D (21). Theseproteins are part of the MADS box family of transcription factors,which include serum response factor and the yeast protein MCM1.The MEF2 proteins share extensive homology in their MADS box domainsand in a short MEF2-specific domain following the MADS box (reviewedin reference 45). These regions include their DNA binding anddimerization domains. There is little or no similarity among thefamily members outside the MADS box-MEF2 domain. We found thatthe predominant type of MEF2 factor binding to the c-jun MEF2site in HeLa cells was MEF2D, with minor binding by MEF2A (21).

The intracellular pathways which link cell surface receptors such as the EGF receptor to the c-jun promoter are unknown. Wehave investigated the role of a number of signalling componentsknown to be activated by EGF. The best characterized of theseis Ras (41, 62). Ras can activate a number of effectors, includingthe protein kinase Raf and phosphatidylinositol 3-kinase (PI3K)(39). Ras can also activate Rac and Rho, members of the Rhofamily of small GTPases (53). Rac can in turn activate a proteinkinase cascade which leads to the activation of JNK. This cascadehas not been completely elucidated but includes the protein kinaseMEKK, which phosphorylates JNKK, which then phosphorylates andactivates JNK (13, 36, 57). JNK can phosphorylate and activateseveral transcription factors, including the c-jun product, ATF2,and Elk-1 (16, 23, 61, 68). Cdc42Hs is another memberof the Rho family that can also activate JNK, but it does notappear to be activated by Ras (11, 32, 44, 48). The Rhofamily GTPases can also activate the c-fos serum response element(SRE) independently of Elk-1 (or its related family members),though the mechanism is still unknown (24).

In this report we show that EGF uses the Ras-to-Rac-to-MEKK pathway to activate the c-jun promoter. We also show that thec-jun AP1-like site binds ATF1 and CREB proteins in HeLa cellsand that both the ATF and MEF2 sites are critical for EGF andRac/Cdc42 responsiveness of the c-jun promoter.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Plasmids. (i) Luciferase reporter genes. Plasmids pJC6GL3, pJSXGL3, pJTXGL3, and pJSTXGL3 contain positions $-$ 225 to +150 of the murine c-jun promoter. The HindIII-XhoIfragments of pJC6, pJSX, pJTX, and pJSTX (20) were subclonedinto the pGL3-luciferase vector (Promega) upstream of the fireflyluciferase gene. pJSXGL3, pJTXGL3, and pJSTXGL3 contain mutationsat the MEF2 site, ATF (AP1-like) site, and both sites, respectively,as described previously (20). pJC7GL3 and pJC9GL3 were generatedby subcloning the HindIII-XhoI fragment of pJC7 and pJC9 (20)upstream of the luciferase gene in pGL3. pJC7GL3 contains positions $-$ 133 to +150 of the c-jun promoter, while pJC9GL3 contains positions $-$ 80 to +150.

pOFLucGL3 contains the minimal promoter of the human c-fos gene ( $-$ 53 to +42) upstream of the luciferase gene in pGL3. Thec-jun promoter fragments of pJF6, pJF7, pJF9, and pJF10 were generatedwith PCR primers that flanked their respective ends, digestedwith HindIII and BglII, and subcloned upstream of the c-fos promoterin pOFLucGL3. pJF6 contains positions $-$ 225 to $-$ 31 of the c-junpromoter; pJF7 contains $-$ 133 to $-$ 31, pJF9 contains $-$ 77 to $-$ 31,and pJF10 contains $-$ 225 to $-$ 80. pFos-GL3 contains $-$ 356 to +109of the murine c-fos promoter upstream of the luciferase gene inpGL3.

(ii) Expression vectors. The following mammalian expression vectors for activated signalling molecules were used: RacI(V12) in pCGT (29), Cdc42Hs(V12)in pCMV5 (32), RhoA(V14) in pEXV (51), and Ras(V12) in pSVSPORT(provided by C. Chandra Kumar). pRafBXB was used as an activatedform of c-Raf (7), and pMEKE in pcDNA3 was used as an activatedform of MEK1 (11). Overexpression of an N-terminal truncatedMEKK1 in pCMV5 was used to increase MEKK activity in cells (42).p110* in pCG (25) was used as an activated form of the catalyticsubunit of PI3K.

For dominant negatives, we used Cdc42(N17) in pCMV5 (44), RhoA(N19) in pEXV (51), RacI(N17) in pEXV (53), MEKK $Delta$ (K432M)in pSR $alpha$ (42), and Ras(N17) in pSR $alpha$ (44); for c-Raf, we usedRaf324FH6 in pLNCX (gift of C. Chandra Kumar).

Transfections and luciferase assays. HeLa cells were grown in Dulbecco's modified Eagle's medium supplemented with 10% newborn calf serum. Duplicates of a 60-mm-diameterplate were transfected by the calcium phosphate coprecipitationmethod (56). The c-jun promoter reporter plasmids (1 µg), theinternal control pCMV- $beta$ -galactosidase (2 µg), and the indicatedamounts of expression vectors were transfected, keeping the totalDNA at 10 µg per plate with herring sperm DNA. At 16 to 20 h aftertransfection, the medium was changed; 8 to 12 h later, the cellswere serum starved in Dulbecco's modified Eagle's medium with0.2% serum for 24 to 30 h. Cells were either untreated or treatedwith EGF at 100 ng/ml for 3 h prior to lysis of cells for luciferaseand $beta$ -galactosidase assays. Preparation of cell extracts wereperformed as specified by the manufacturer (Promega) and as describedpreviously (28). Luciferase and $beta$ -galactosidase assays weredescribed previously (28). All luciferase values were normalizedto $beta$ -galactosidase activities. The p38 inhibitor SB203580 (Calbiochem)was added at 10 µM 30 min before EGF addition to cells transfectedwith pJC6GL3. TPA at 100 ng/ml was used to induce cells transfectedwith pFos-GL3 (1 µg) as described above for EGF induction of pJC6GL3.

Antibodies. The anti-c-Jun/AP1(D) (sc-44) and anti-c-Fos(K25) (sc-253) sera were affinity-purified rabbit polyclonal antibodies from SantaCruz Biotechnology. The anti-c-Jun serum AJ2 was an affinity-purifiedrabbit polyclonal antibody from Oncogene Research Products, Calbiochem(PC06L). For the anti-c-Jun serum AJ1, histidine-tagged rat c-juncDNA in the expression vector pDS56 (a gift from Tom Curran) wasexpressed in Escherichia coli MC15 cells and isolated by nickelaffinity chromatography under denaturing conditions as describedpreviously (1). Purified protein was loaded on a sodium dodecylsulfate (SDS)-polyacrylamide gel, and the gel slice was injectedinto rabbits to generate sera.

The anti-CREB antiserum was kindly provided by Michael E. Greenberg and was described previously (14). The anti-ATF3 serawere generated by injection of recombinant ATF3 to rabbits asdescribed previously (69). For the anti-ATF1 serum, histidine-taggedhuman ATF1 (in pET3b vector) was expressed in E. coli BL21(DE3)LysS,isolated by nickel affinity chromatography under denaturing conditions,and loaded on an SDS-polyacrylamide gel. The gel slice was injectedinto rabbits to generate antisera. For the anti-ATF4 serum, apartial human ATF4 cDNA encoding amino acids 207 to 351 was clonedin the pET3b vector and expressed in E. coli BL21(DE3)LysS asdescribed by Studier et al. (60). Because the recombinant proteinhad a high expression level but low solubility, the inclusionbody which contained mostly the recombinant protein was resuspendedin SDS-polyacrylamide gel electrophoresis loading buffer and loadedon an SDS-polyacrylamide gel without further purification. Thegel slice was injected into rabbits to generate antiserum. TheATF-2 antibody (9222) was an affinity-purified rabbit polyclonalantibody from New England Biolabs.

Oligonucleotides. The jATF probe was a 25-bp double-stranded oligonucleotide containing the sequence spanning the murine c-Jun ATF site, previouslycalled the c-Jun AP-1 site (20) (5'-TCGAGCTCGGGGTGACATCATGGGA-3'and 5'-GATCTCCCATGATGTCACCCCGAGC-3'). The AP1 probe was a 22-bpdouble-stranded oligonucleotide containing the AP-1 consensusrecognition sequence (5'-TCGAGCGTGACTCAGCGCGCGA-3' and 5'-GATCTCGCGCGCTGAGTCACGC-3').

Gel mobility shift assays. For in vitro expression, ATF1, ATF2, and ATF4 open reading frames were inserted in the pTM1 expression vector (47), whilec-jun was inserted in pGEM. Coupled transcription-translationusing the reticulocyte lysate system was performed as specifiedby the manufacturer (Promega).

Nuclear extracts from HeLa cells were prepared and gel mobility shift assays were performed as described previously (50).Double-stranded oligonucleotides used as probes were labeled withpolynucleotide kinase and [ $gamma$ -³²P]ATP. The DNA binding reactions were performed at room temperaturewith 1 ng of the ³²P-labeled probe for 30 min. In each assay, 2 µg of herring spermDNA was included as nonspecific competitor. For antibody supershiftexperiments, the binding reaction mixtures were incubated with0.2 to 2 µl of nonimmune or immune serum for 30 min at room temperaturebefore addition of the probe. The DNA-protein complexes were separatedby electrophoresis on 4% polyacrylamide-0.25× TBE (25 mM Trisbase, 25 mM boric acid, 1 mM EDTA) gels.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Sequence elements required for EGF induction of the c-jun promoter. Using c-jun-chloramphenicol acetyltransferase (CAT) reporter genes and RNase protection assays, it was previously shown thatEGF induction of the c-jun promoter requires a MEF2 site at $-$ 59in the c-jun promoter (20). An AP1-like element at $-$ 72 was alsofound to be required for the general level of Jun-CAT expressionbut was not clearly involved in EGF induction. To analyze thec-jun promoter, we have transfected HeLa cells with c-jun promoter-luciferasereporter genes. EGF treatment of cells transfected with pJC6GL3,which contains positions $-$ 225 to +150 of the mouse c-jun promoter,resulted in fourfold induction of expression of the jun-luciferasegene (Fig. 1). The use of the pGL3-luciferase vector (Promega)was critical in our experiments since the vector was designedto remove a number of potential binding sites for site-specifictranscription factors. We obtained anomalous results with c-junpromoter mutants using other forms of luciferase genes, presumablydue to these cryptic sequence elements (data not shown).

View larger version (19K):
[in this window]
[in a new window]

FIG. 1. (A) MEF2 and ATF sites are required for EGF induction of the c-jun promoter. HeLa cells were transiently transfected with the c-jun pGL3-luciferase reporter plasmids, as indicated, and pCMV- $beta$ -galactosidase as an internal control. After transfection, the cells were serum starved and treated with or without EGF (100 ng/ml) for 3 h before preparing cell lysates for luciferase and $beta$ -galactosidase assays. The fold induction of luciferase activity in EGF-treated cells relative to untreated cells is shown. Values shown are the averages of at least two separate experiments done in duplicate ± standard errors of the means. (B) c-jun promoter constructs. The positions of binding sites for the transcription factors SP1, CTF, ATF, and MEF2 are indicated. The ATF site was previously referred to as an AP1-like element. The regions of the c-jun promoter in each construct are indicated. Point mutations in the ATF or MEF2 sites are indicated (x). LUC, luciferase.

We tested the requirements of c-jun promoter elements for EGF induction by assaying different deletion mutants. A Jun-luciferaseconstruct with 1.6 kb of the human c-jun promoter behaved similarlyto pJC6GL3 (data not shown). Deletion to $-$ 133 of the mouse c-junpromoter in pJC7GL3 also had no effect on induction. Deletionto $-$ 80 (pJC9GL3) decreased induction to about 2.5-fold (Fig. 1).pJC9GL3 contains both the MEF2 and AP1-like elements, suggestingthat sequence elements upstream of $-$ 80 may also function in EGF-inducedexpression.

To determine their individual contributions to EGF inducibility, we made mutations in the MEF2 and AP1-like sites of pJC6GL3(plasmids pJSXGL3 and pJTXGL3, respectively). Mutations in eithersite reduced EGF induction by about 50% (Fig. 1). A constructcontaining a double mutation at these sites, pJSTXGL3, almostcompletely abolished EGF induction. These results suggest thatboth the MEF2 and AP1-like sites of the c-jun promoter are requiredfor EGF induction although partial induction can occur withouteither site.

To determine which sequence elements in the c-jun promoter were sufficient for EGF induction, we assayed various segmentsupstream of a minimal c-fos promoter. This minimal promoter inpOFlucGL3 contains a TATA box but not other known elements andwas not inducible by EGF (Fig. 2). We found that the region from $-$ 225 to $-$ 31 of c-jun was sufficient to cause the minimal promoterto be induced fivefold by EGF (pJF6 in Fig. 2). A smaller regionof the c-jun promoter, $-$ 133 to $-$ 31, was similarly inducible (pJF7),but removal of 5' sequences from $-$ 133 to $-$ 78 reduced inductionto about 2.5-fold (pJF9 [Fig. 2]). This last construct containsboth the MEF2 and AP1-like sites but was poorly inducible, suggestingthat elements between $-$ 133 and $-$ 77 are required for full induction.This region contains both CAAT and SP1 elements. We tested whetherthis region was sufficient for EGF induction by placing the regionfrom $-$ 225 to $-$ 80 on the minimal c-fos promoter. Expression fromthis construct, pJF10, was not inducible by EGF (Fig. 2). Together,the results in Fig. 1 and 2 suggest that the MEF2 and AP1-likeelements function together to mediate EGF induction and that theyrequire additional upstream element(s) for full induction.

View larger version (16K):
[in this window]
[in a new window]

FIG. 2. (A) Upstream elements cooperate with ATF and MEF2 sites for EGF induction of the c-jun promoter. HeLa cells were transiently transfected with the indicated reporter plasmids (3 µg) and assayed for EGF induction of luciferase activity as described for Fig. 1. (B) Heterologous c-jun promoter constructs. The indicated fragments of the c-jun promoter were cloned upstream of a minimal c-fos promoter (shaded in grey) and a luciferase (LUC) reporter gene.

ATF1 is the predominant factor in HeLa nuclear extracts that binds to the c-jun AP1-like element. We used gel mobility shift assays with HeLa nuclear extracts to determine which factors bind to the c-jun AP1-like element.We observed two specific bands in gel mobility shift assays usinga labeled oligonucleotide spanning the c-Jun AP1-like site (complexes1 and 2 [Fig. 3, lane 1]). These bands were competed by excessunlabeled oligonucleotide probe (lane 2). We also tested extractsfrom HeLa cells treated with EGF for 5 to 60 min for binding activityto the c-jun AP1-like site. There was no change in the migrationor amount of the complexes (data not shown). These results suggestthat regulation is not exerted by changing the amount or typeof these complexes.

While the site at $-$ 72 was previously termed an AP1-like site (2), its sequence, TGACATCA, is more similar to a consensusATF site, TGACGTCA, than to a consensus AP1 site, TGACTCA. Forthis reason, we used antibodies against ATF family members aswell as against Fos and Jun, components of AP1 complexes, to inhibitor supershift the bands in gel mobility shift assays. Nonimmuneserum or antisera for Fos, Jun, ATF3, or ATF4 had no effect onthe complexes (Fig. 3). Antiserum to CREB, a member of the ATFfamily, abolished the upper band while having little effect onthe bottom complex (lane 6). Antiserum to ATF1 inhibited bothcomplexes and caused a weak supershifted complex (complex 3 [lane7]). The ATF1 and CREB antisera had no effect on a MEF2 gel mobilityshift complex (data not shown). Since ATF1 and CREB can heterodimerize(26), these results are consistent with the bottom predominantband being an ATF1 homodimer while the upper band is an ATF1-CREBheterodimer. We cannot rule out, however, the possibility thatATF1 or CREB heterodimerize with other partners. We will henceforthrefer to the c-jun AP1-like site as the jun ATF site.

View larger version (58K):
[in this window]
[in a new window]

FIG. 3. ATF1 and CREB from HeLa nuclear extracts bind to the c-Jun ATF site. Gel mobility assays were performed with HeLa cell nuclear extracts and a ³²P-labeled double stranded oligonucleotide spanning the c-jun ATF site as a probe. A 50-fold molar excess of unlabeled oligonucleotide (jATF) was included as a specific competitor as indicated. Other nonspecific oligonucleotides had no effect (data not shown). The addition of antisera to the indicated proteins is shown. NRS, normal rabbit serum; $-$ , no serum added. The arrows indicate the DNA-protein complexes obtained.

As controls for the specificity and effectiveness of the antisera, we have found that the anti-ATF3 serum can specificallysupershift in vitro translated ATF3 (69) and that the anti-ATF4serum supershifted in vitro-translated ATF4 but not ATF1 (datanot shown). The anti-Fos serum partially inhibited the gel shiftof HeLa nuclear extract to a consensus AP1 site (data not shown).Two additional batches of anti-Jun serum also had no effect onthe gel shift of HeLa nuclear extract to the jun ATF site. Thesetwo sera (AJ1 and AJ2) were able to completely supershift in vitro-translatedc-Jun but not ATF1 (data not shown).

ATF1 and CREB cannot heterodimerize with either c-Jun or ATF2 in vitro (4, 17, 18). We further tested whether ATF2is in the complex, however, since it can be activated by Rac andJNK and can bind to ATF sites (16). Antiserum to ATF2 had noeffect on the complex from HeLa nuclear extracts, while anti-ATF1completely supershifted the complexes (Fig. 4A, lanes 12 and 13).The anti-ATF2 serum was able to supershift in vitro-translatedATF2 (compare lanes 5 and 8) but had no effect on in vitro-translatedATF1 (lane 4). Conversely, the anti-ATF1 serum was able to supershiftin vitro-translated ATF1 but not ATF2 (lanes 3 and 7), furtherdemonstrating its specificity. We used a consensus AP1 site totest whether this site is similar to the jun ATF site. We detecteda complex (band E [Fig. 4B, lane 1]) which could be specificallycompeted by the AP1 site (data not shown). This band migratedslightly below the bands binding to the jun ATF site (data notshown). The AP1 site complex was not affected by the anti-ATF1serum (lane 3), demonstrating that the Jun ATF and AP1 sites binddistinct factors. We observed a complex in all lanes containingthe control normal rabbit serum due to a nonspecific factor inthis serum preparation.

View larger version (35K):
[in this window]
[in a new window]

FIG. 4. Antisera to ATF1, but not ATF2, specifically affect the c-Jun ATF complexes. (A) Gel mobility shift assays were performed with the c-jun ATF site probe and in vitro-translated ATF1 (lanes 1 to 4), in vitro-translated ATF2 (lanes 5 to 8), mock in vitro translation extract (lane 9), or HeLa cell nuclear extracts (lanes 10 to 13). Either no serum ( $-$ ), nonimmune serum (NRS), or anti-ATF1 or anti-ATF2 serum was added as indicated. (B) HeLa nuclear extracts were assayed with an AP1 consensus site probe and the indicated sera. Arrows D and C mark complexes obtained with in vitro-translated ATF1 and ATF2. Antibody-supershifted complexes are marked with arrows A and B. Complex E shows the complex binding to the consensus AP1 site. The arrowheads to the right indicate a nonspecific complex obtained with nonimmune serum.

The small G proteins Rac1 and Cdc42 can activate the c-jun promoter. We were interested in identifying intracellular signalling pathways involved in EGF signalling from its cell surface receptorto the c-jun promoter. We first used a number of activated formsof known signalling molecules. EGF is known to activate Ras (41,62), and we found that activated Ras [Ras(V12)] increased expressionfrom the c-jun reporter gene pJC6GL3 (Fig. 5). One direct targetof Ras is Raf, which activates a protein kinase cascade leadingto activation of the Erk mitogen-activated protein kinases (MAPKs)(46, 66, 67). An activated form of Raf (RafBXB), however,did not increase expression from pJC6GL3 (Fig. 5). In addition,an activated form of MEK, a protein kinase activated by Raf, didnot increase expression from pJC6GL3 (data not shown). Anotherdirect effector of Ras is PI3K. An activated form of the p110subunit of PI3K (25), however, did not significantly activatethe jun reporter pJC6GL3 (data not shown). As controls, we foundthat the Raf, MEK1, and p110 constructs increased expression ofa c-fos promoter reporter gene (data not shown).

View larger version (36K):
[in this window]
[in a new window]

FIG. 5. Activation of the c-jun promoter by activated forms of the small G proteins Ras, Rac, and Cdc42Hs. HeLa cells were transiently transfected with the c-jun-luciferase reporter pJC6GL3, pCMV- $beta$ -galactosidase as an internal control, and the following expression vectors (3 µg of each except for 2 µg for MEKK): pcDNA3 (empty vector control), Ras(V12), RafBXB, Cdc42Hs(V12), RacI(V12), RhoA(V14), or MEKK1. Cells were serum starved overnight prior to lysis for luciferase and $beta$ -galactosidase assays. The fold induction of luciferase activity is shown relative to activity in cells transfected with an empty expression vector (pcDNA3). The luciferase activities were normalized to the $beta$ -galactosidase activities except for assays with RasV12. With RasV12, the activity from pCMV- $beta$ -galactosidase was consistently induced fourfold, and this change was compensated for in normalizing the effect of Ras on pJC6GL3. The values shown are the averages of at least two separate experiments done in quadruplicate ± standard errors of the means.

The small GTPases RacI and RhoA were reported to be activated by Ras (53). Cdc42Hs is highly related to RacI, and both canactivate the protein kinase JNK (11, 44). Both activated RacIand Cdc42Hs activated the c-jun promoter, while activated RhoAonly weakly increased expression (Fig. 5). The RhoA vector wasactive since it was able to increase expression of a c-fos SREreporter gene (data not shown).

Since Cdc42Hs and RacI are known to activate a pathway leading to activation of JNK, we tested an upstream component of theJNK pathway, MEKK. Overexpression of this protein kinase is sufficientto activate JNK (42) and also resulted in activation of thec-jun promoter (Fig. 5).

None of the activators except Ras significantly affected the internal control plasmid pCMV- $beta$ -galactosidase, suggesting thattheir effect on the c-jun promoter is specific. Ras(V12) increasedpCMV- $beta$ -galactosidase up to fourfold, but we compensated for thisincrease in the data presented in Fig. 5.

We tested whether activation of the c-jun promoter by RacI required the MEF2 and ATF sites. We found that RacI did not activatepJF10, which lacks the MEF2 and ATF sites (shown in Fig. 2), whilepJF6 was strongly induced (data not shown). In addition, as seenin Fig. 6, mutation of either of the MEF2 or ATF sites in pJC6GL3strongly reduced activation of the promoter by Rac. Mutation ofboth sites caused a further reduction of activity. Similar resultswere obtained with Cdc42Hs (data not shown). These results aresimilar to those obtained with EGF (Fig. 1) and suggest that RacIand Cdc42Hs act through both the MEF2 and ATF sites.

View larger version (27K):
[in this window]
[in a new window]

FIG. 6. Requirement of the MEF2 and ATF sites for Rac activation of the c-jun promoter. HeLa cells were transiently transfected with the indicated reporter genes, pCMV- $beta$ -galactosidase as an internal control, and either 2.5 µg of empty expression vector (pcDNA3) or racI(V12). After transfection, cells were serum starved in 0.2% newborn calf serum overnight and then lysed for luciferase and $beta$ -galactosidase assays. Relative luciferase activities normalized to the $beta$ -galactosidase activities are shown. The values shown are the averages of two separate experiments done in duplicate ± standard errors of the means.

Dominant negative Ras, RacI, and MEKK can block EGF induction of the c-jun promoter. We used dominant negative forms of the signalling molecules to test whether Ras, RacI, and MEKK are required for EGF inductionof the c-jun promoter. We transfected expression vectors containingthe dominant negative constructs together with the c-jun reporterplasmid pJC6GL3. Expression of dominant negative mutants of MEKKand Ras strongly reduced EGF induction from about fivefold totwofold (Fig. 7A). In contrast, dominant negative forms of Cdc42Hs(Fig. 7A) and of RhoA and Raf (data not shown) had no effect onEGF-induced Jun-luciferase expression.

View larger version (20K):
[in this window]
[in a new window]

FIG. 7. Dominant negative Ras, RacI, and MEKK block EGF induction of the c-jun promoter. (A) HeLa cells were transiently transfected with pJC6GL3, pCMV- $beta$ -galactosidase, and 1 µg of the empty expression vector pcDNA3 or the indicated dominant negative vectors. After transfection, cells were serum starved for 30 h and then treated with or without EGF (100 ng/ml) for 3 h prior to lysis for luciferase and $beta$ -galactosidase assays. The fold induction in EGF-treated relative to untreated cells is shown. The results are the means of duplicates ± standard errors of the means. (B) HeLa cells were transiently transfected with the c-fos reporter plasmid pFos-GL3 (1 µg), pCMV- $beta$ -galactosidase (1.5 µg), and the indicated dominant negative vectors as for panel A except that the cells were treated with or without TPA (100 ng/ml) for 3 h. The fold induction by TPA relative to untreated cells is shown. (C) Increasing amounts of dominant negative RacI were transfected as for panel A with the c-jun reporter gene except that EGF was added at 200 ng/ml. (D) Increasing amounts of RacI(N17) were transfected with the c-fos reporter gene and assayed for the effect on TPA induction as for panel B.

To demonstrate the specificity of the dominant negative mutants, we tested their ability to inhibit TPA induction of a c-fos-luciferasereporter gene. TPA induction of the c-fos promoter acts primarilythrough an Erk MAPK pathway which is activated by protein kinaseC downstream of Ras (reviewed in reference 64). As expected,TPA induction of the c-fos reporter was not significantly affectedby the dominant negative mutants (Fig. 7B).

To test the effect of dominant negative RacI [RacI(N17)] on EGF induction of the c-jun promoter, we titrated the amount oftransfected construct since we observed some nonspecific inhibitionon TPA induction of the c-fos promoter when transfecting highamounts of RacI(N17) (data not shown). In the experiment shownin Fig. 7C, increasing amounts of dominant negative RacI inhibitedEGF induction by greater than 50%. No effect was observed on TPAinduction of the c-fos reporter with the lower amounts of RacI(N17)used, while 2 µg of RacI(N17) caused a slight reduction (Fig.7D). These results with dominant negative inhibitors suggest thatRas, RacI, and MEKK are required for EGF signalling to the c-junpromoter.

Recently the MAPK p38 and its activator MEK6 were found to activate the c-jun promoter (19). In addition, expression ofMEKK at high levels can activate p38 (59, 72). We found, however,that the p38 inhibitor SB205380 had no effect on EGF inductionof the c-jun promoter, suggesting that p38 is not required (datanot shown). However, two homologs of p38, p38 $gamma$ and SAPK4, areinsensitive to this inhibitor (33) such that they or other relatedkinases could be involved in activation of the c-jun promoter.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

We have shown that the Ras-RacI-MEKK pathway is necessary and sufficient for EGF induction of the c-jun promoter. This pathwayappears to operate predominantly through two sequence elements,ATF and MEF2 sites, which are bound by ATF1 and MEF2D in HeLacells.

Sequence elements for EGF induction of the c-jun promoter. The MEF2 site at $-$ 59 and an ATF site at $-$ 72 in the c-jun promoter were found to be required for EGF induction. Mutation ofeither site reduced induction but did not abolish it, suggestingthat each element can at least partially function without theother. The mutation of both sites abolished induction, yet thesesites do not completely account for induction since they werenot sufficient for maximal induction.

An additional region of the promoter, from $-$ 133 to $-$ 77, was needed for full induction. This region includes potential SP1,CAAT box, and ets sites, although we have not determined which,if any, of these sites are required for maximal induction. Thisregion of the promoter was not sufficient for even partial EGFinduction on a heterologous promoter but rather increased inductionby the MEF2-ATF segment of the c-jun promoter. Factors bindingbetween $-$ 133 and $-$ 77 upstream of the MEF2 and ATF sites may interactwith the MEF2 and ATF factors to increase transcriptional activation.It is also possible, however, that the upstream factors are regulatedby EGF but are not sufficient to activate the promoter withoutATF and/or MEF2 factors.

We previously found that the MEF2 and ATF sites were critical for EGF induction (20) but have found slightly different resultshere. The first difference from our previous work (20) is inthe role of the ATF site. Using RNase protection assays to measureexpression, we observed no effect of mutation of the ATF sitein the context of a $-$ 225 c-jun promoter-CAT reporter gene, althoughreduced expression was found following mutation of the ATF sitein a $-$ 80 c-jun promoter construct. A second difference is in theability of the MEF2 and ATF sites to give maximal induction withoutadditional sequence elements. Here we have found that the MEF2-ATFsites give only modest induction which was increased when upstreamsequence was present (Fig. 1 and 2). We believe that the differencesare due to cryptic transcription factor binding sites in the originalreporter genes used. In this study, we used the pGL3-luciferasevector which has been specifically designed to remove potentialATF, AP1, AP2, and SP1 sites in the luciferase gene. Consistentwith this notion, comparison of EGF induction of the c-jun promoterin the previous luciferase vector with that in pGL3 showed thatmutations in the MEF2 and ATF sites have much more pronouncedeffects in the context of the pGL3 vector (data not shown).

The c-fos promoter also contains an ATF site which is involved in nerve growth factor induction of the promoter (5). Whilethe c-fos ATF site (termed a cyclic AMP response element at $-$ 60)is not inducible alone, it can accentuate induction together withother c-fos elements (such as the SRE) (5). This situationis similar to that with c-jun, where the ATF site alone givesweak induction but is required for maximal induction of the promoter.

Factors binding at the ATF and MEF2 sites. The ATF site at $-$ 72 of the c-jun promoter was originally termed an AP1 site based on its binding to recombinant c-jun (2).As noted by Smith et al., however, this site more closely resemblesa consensus ATF site (58). Using specific antisera, we haveshown that the predominant factor binding this site in HeLa cellnuclear extracts is ATF1, with lesser binding by CREB. ATF1 andCREB are closely related proteins that can form heterodimers (26)such that the complex affected by the anti-CREB serum is likelyto be a heterodimer of ATF1 and CREB. Our results are consistentwith those of Hurst et al., who showed that in HeLa cell extracts,ATF1 homodimers along with ATF1-CREB heterodimers bound to ATFsites (26). Smith et al. detected four complexes binding tothe c-jun ATF site in CCL64 cell extracts (58). Similar to ourresults, one complex was affected by anti-CREB serum, but twoother complexes were affected by antiserum to another ATF familymember, ATFa (58). This difference could be due to the differentcell types used. Inconsistent with our results, Herr et al. foundin HeLa extracts that Fos and Jun along with some ATF2 bound tothe jun ATF site (which they termed jun1TRE) (22). The differentresults may be due to differences in the batches of HeLa cells,the exact experimental conditions, or the specificity of the antiseraused.

While our results suggest that ATF1 homodimers and ATF1-CREB heterodimers bind to the c-jun ATF site in HeLa cells, we cannotrule out the possibility that other factors heterodimerize witheither of these factors. Since c-Jun and ATF2 can be phosphorylatedand activated by JNK, which in turn can be activated by RacI (16,23, 61), we tested whether either of these proteins mightbe in the complex. Antisera to both had no effect on the complex.In addition, ATF1 and CREB did not heterodimerize with eitherc-Jun or ATF2 when examined in vitro (4, 17, 18), suggestingthat c-Jun and ATF2 are most likely not in the complex.

Overexpression of c-jun was previously found to activate the c-jun promoter through the c-jun AP1-like site, suggesting adirect positive autoregulatory loop (2). The finding that ATFfamily members preferentially bind to this site, rather than c-Junitself, suggests that the autoregulation is not direct but involvesactivation of ATF1 or CREB by an indirect mechanism. It is possible,however, that when c-jun is overexpressed it will directly occupythe jun ATF site even though this does not appear to occur underphysiological conditions.

Four MEF2 family members, MEF2A to MEF2D, can bind to MEF2 sites. We previously found, using specific sera, that MEF2D isthe predominant factor in HeLa cell extracts that binds to thec-jun MEF2 site, with MEF2A accounting for about 10% of the complex(21). The proportion of these and other family members is likelyto vary in different cell types. Ornatsky and McDermott foundthat MEF2A is the predominant factor in C2C12 myotubes (49).Using our sera, they also found that MEF2A was as abundant asMEF2D in HeLa cells. This result likely reflects different batchesof HeLa cells and demonstrates the variability of expression ofthese family members.

Signalling pathways. Using activated and dominant negative forms of signalling molecules, we have found that EGF induction of the c-jun promoteracts through Ras, Rac, and MEKK. The proposed pathway is shownin Fig. 8. EGF induction of Ras is mediated by EGF receptor bindingto GRB2 and Sos, a guanine nucleotide exchange factor for Ras(9, 35). Ras can then activate Rac, though the mechanismis still unknown (53). MEKK functions downstream of Rac (44),although there is likely at least one intermediary between Racand MEKK. A number of protein kinases have been found to bindRac, but it is unclear which if any of these is involved in activationof MEKK (37, 38, 40). MEKK activates the protein kinaseJNKK, which in turn activates JNK (13, 42, 57, 73). EGFcan efficiently activate this pathway, as shown by EGF inductionof JNKKinase activity (8, 43). We have demonstrated thatthe Ras-Rac-MEKK pathway is involved in EGF signalling to thec-jun promoter but have not determined which proteins downstreamof MEKK are involved. Activated and dominant negative forms ofJNK are either not available or not very effective, and thus wewere not able to clearly determine its involvement. Therefore,activation of the c-jun promoter could involve JNK or a separatepathway downstream of MEKK, as indicated by the question marksin Fig. 8. Investigation of how the transcription factors on thec-jun promoter are regulated will help clarify this point.

View larger version (19K):
[in this window]
[in a new window]

FIG. 8. Model of signalling pathways for EGF activation of c-jun. Components for signalling pathways to the c-jun promoter and for phosphorylation of c-Jun protein are shown and are described in the text. The pathway for induction of the c-jun promoter downstream of MEKK is unknown and may involve JNK and/or a separate pathway as indicated by the question marks. Two arrows between components indicate that the activation of the protein is not direct.

Cdc42Hs was also able to activate the c-jun promoter, but it is unlikely to be involved in the EGF-stimulated pathway. First,dominant negative Cdc42Hs did not inhibit EGF induction. Second,studies with dominant negative Cdc42Hs mutants suggest that Cdc42does not operate between Ras and Rac (32, 48). The closelyrelated GTPase Rho also does not appear to be involved in signallingto the c-jun promoter, since activated Rho strongly activatedthe fos promoter but not the jun promoter. Likewise, two othermolecules downstream of Ras, Raf and the p110 subunit of PI3K,do not appear to be involved since activated forms of these moleculesdid not activate the c-jun promoter.

It has been reported that activators of the MAPK p38 can activate the c-jun promoter (19). Rac can also activate p38, althoughMEKK activates only p38 when it is expressed at high levels (36,59, 72, 74). An inhibitor of p38 $alpha$ and - $beta$ had no effect onEGF induction, suggesting that these kinases are involved, thoughwe cannot rule out that other homologs or related kinases mediateactivation. There could also be redundancy of p38 and JNKK suchthat inhibition of p38 had no effect.

It is unclear as yet how the factors on the c-jun promoter are regulated. MEF2C was recently shown to be regulated by p38phosphorylation (19). However, MEF2C is not present in HeLacells (49), the region of MEF2C that is phosphorylated is notconserved in MEF2D, and as mentioned above, a p38 inhibitor didnot inhibit EGF induction. Our preliminary experiments did notreveal EGF-induced changes in MEF2D phosphorylation (21), buta more careful analysis is required. In vivo footprinting studieshave shown that the c-jun MEF2 site is occupied before and afterserum treatment (54). We have also found that MEF2D DNA bindingactivity does not change in EGF-treated HeLa cell nuclear extracts,suggesting that regulation is likely to be on MEF2D's transcriptionalactivation function rather than its DNA binding activity (21).This may be due to posttranslational modifications or complexingwith regulatory proteins.

We did not find a change in binding to the jun ATF site in extracts from EGF-treated cells. One other potential mechanismfor regulation of ATF1 and CREB is phosphorylation. Phosphorylationof CREB and ATF1 was induced by fibroblast growth factor, nervegrowth factor, or EGF in various cell lines (5, 27, 63).This phosphorylation was found to be either p38 dependent (27,63) or MEK1 (an activator of ERKs) dependent (71). These requirementsare different from what we have found here for EGF induction ofthe c-jun promoter in HeLa cells. ATF1 and CREB can be phosphorylatedand activated by a number of protein kinases, including cyclicAMP-dependent protein kinase (protein kinase A), MAPKAP kinase-2,and RSK2 (15, 63, 71). Further study will be needed to determinewhether phosphorylation of ATF1 or CREB is required for inductionof the c-jun promoter and, if so, which protein kinases are involved.

	ACKNOWLEDGMENTS

We thank Michael Greenberg, C. Chandra Kumar, and J. Silvio Gutkind for their kind gifts of antisera and plasmids.

This work was supported by grant BE-261 from the American Cancer Society.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biological Sciences, Columbia University, 1212 Amsterdam Ave. MC2420,New York, NY 10027. Phone: (212) 854-8281. Fax: (212) 865-8246.E-mail: mrp6{at}columbia.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

1. Abate, C., D. Luk, and T. Curran. 1990. A ubiquitous nuclear protein stimulates the DNA-binding activity of fos and jun indirectly. Cell Growth Differ. 1:455-462[Abstract].

2. Angel, P., K. Hattori, T. Smeal, and M. Karin. 1988. The jun proto-oncogene is positively autoregulated by its product, Jun/AP-1. Cell 55:875-885[Medline].

3. Angel, P., and M. Karin. 1991. The role of Jun, Fos, and the AP-1 complex in cell-proliferation and transformation. Biochim. Biophys. Acta 1072:129-157[Medline].

4. Benbrook, D. M., and N. C. Jones. 1990. Heterodimer formation between CREB and JUN proteins. Oncogene 5:295-302[Medline].

5. Bonni, A., D. D. Ginty, H. Dudek, and M. E. Greenberg. 1995. Serine 133-phosphorylated CREB induces transcription via a cooperative mechanism that may confer specificity to neurotrophin signals. Mol. Cell. Neurosci. 6:168-183[Medline].

6. Brenner, D. A., M. O'Hara, P. Angel, M. Chojkier, and M. Karin. 1989. Prolonged activation of jun and collagenase genes by tumor necrosis factor- $alpha$ . Nature 337:661-663[Medline].

7. Bruder, J. T., G. Heidecker, and U. R. Rapp. 1992. Serum-, TPA-, and ras-induced expression from Ap-1/Ets-driven promoters requires Raf-1 kinase. Genes Dev. 6:545-556[Abstract/Free Full Text].

8. Cano, E., C. A. Hazzalin, and L. C. Mahadevan. 1994. Anisomycin-activated protein kinases p45 and p55 but not mitogen-activated protein kinases ERK-1 and -2 are implicated in the induction of c-fos and c-jun. Mol. Cell. Biol. 14:7352-7362[Abstract/Free Full Text].

9. Chardin, P., J. H. Camonis, N. W. Gale, L. van Aelst, J. Schlessinger, M. H. Wigler, and D. Bar-Sagi. 1993. Human Sos1: a guanine nucleotide exchange factor for Ras that binds to GRB2. Science 260:1338-1343[Abstract/Free Full Text].

10. Chen, B. P. C., C. D. Wolfgang, and T. Hai. 1996. Analysis of ATF3, a transcription factor induced by physiological stress and modulated by gadd153/Chop10. Mol. Cell. Biol. 16:1157-1168[Abstract].

11. Coso, O. A., M. Chiariello, J. C. Yu, H. Teramoto, P. Crespo, N. Xu, T. Miki, and J. S. Gutkind. 1995. The small GTP-binding proteins Rac1 and Cdc42 regulate the activity of the JNK/SAPK signaling pathway. Cell 81:1137-1146[Medline].

12. de Groot, R. P., C. Pals, and W. Kruijer. 1991. Transcriptional control of c-jun by retinoic acid. Nucleic Acids Res. 19:1585-1591[Abstract/Free Full Text].

13. Derijard, B., J. Raingeaud, T. Barrett, I. H. Wu, J. Han, R. J. Ulevitch, and R. J. Davis. 1995. Independent human MAP-kinase signal transduction pathways defined by MEK and MKK isoforms. Science 267:682-685[Abstract/Free Full Text].

14. Ginty, D. D., J. M. Kornhauser, M. A. Thompson, H. Bading, K. E. Mayo, J. S. Takahashi, and M. E. Greenberg. 1993. Regulation of CREB phosphorylation in the suprachiasmatic nucleus by light and a circadian clock. Science 260:238-241[Abstract/Free Full Text].

15. Gonzalez, G. A., and M. R. Montminy. 1989. Cyclic AMP stimulates somatostatin gene transcription by phosphorylation of CREB at serine 133. Cell 59:675-680[Medline].

16. Gupta, S., D. Campbell, B. Derijard, and R. Davis. 1995. Transcription factor ATF2 regulation by the JNK signal transduction pathway. Science 267:389-393[Abstract/Free Full Text].

17. Hai, T., F. F. Liu, W. Coukos, and M. Green. 1989. Transcription factor ATF cDNA clones: an extensive family of leucine zipper proteins able to selectively form DNA-binding heterodimers. Genes Dev. 3:2083-2090[Abstract/Free Full Text].

18. Hai, T., and T. Curran. 1991. Cross-family dimerization of transcription factors Fos/Jun and ATF/CREB alters DNA binding specificity. Proc. Natl. Acad. Sci. USA 88:3720-3724[Abstract/Free Full Text].

19. Han, J., Y. Jiang, Z. Li, V. V. Kravchenko, and R. J. Ulevitch. 1997. Activation of the transcription factor MEF2C by the MAP kinase p38 in inflammation. Nature 386:296-299[Medline].

20. Han, T., W. W. Lamph, and R. Prywes. 1992. Mapping of epidermal growth factor-, serum-, and phorbol ester-responsive sequence elements in the c-jun promoter. Mol. Cell. Biol. 12:4472-4477[Abstract/Free Full Text].

21. Han, T., and R. Prywes. 1995. Regulatory role of MEF2D in serum induction of the c-jun promoter. Mol. Cell. Biol. 15:2907-2915[Abstract].

22. Herr, I., H. Van Dam, and P. Angel. 1994. Binding of promoter-associated AP-1 is not altered during induction and subsequent repression of the c-jun promoter by TPA and UV irrandiation. Carcinogen 15:1105-1113[Abstract/Free Full Text].

23. Hibi, M., A. Lin, T. Smeal, A. Minden, and M. Karin. 1993. Identification of an oncoprotein- and UV-responsive protein kinase that binds and potentiates the c-Jun activation domain. Genes Dev. 7:2135-2148[Abstract/Free Full Text].

24. Hill, C. S., J. Wynne, and R. Treisman. 1995. The Rho family GTPases RhoA, Rac1, and CDC42Hs regulate transcriptional activation by SRF. Cell 81:1159-1170[Medline].

25. Hu, Q., A. Klippel, A. J. Muslin, W. J. Fantl, and L. T. Williams. 1995. Ras-dependent induction of cellular responses by constitutively active phosphatidylinositol 3-kinase. Science 268:100-102[Abstract/Free Full Text].

26. Hurst, H. C., N. F. Totty, and N. C. Jones. 1991. Identification and functional characterisation of the cellular activating transcription factor 43 (ATF-43) protein. Nucleic Acids Res. 19:4601-4609[Abstract/Free Full Text].

27. Iordanov, M., K. Bender, T. Ade, W. Schmid, C. Sachsenmaier, K. Engel, M. Gaestel, H. J. Rahmsdorf, and P. Herrlich. 1997. CREB is activated by UVC through a p38/HOG-1-dependent protein kinase. EMBO J. 16:1009-1022[Medline].

28. Johansen, F., and R. Prywes. 1994. Two pathways for serum regulation of the c-fos serum response element require specific sequence elements a minimal domain of serum response factor. Mol. Cell. Biol. 14:5920-5928[Abstract/Free Full Text].

29. Joneson, T., M. McDonough, D. Bar-Sagi, and L. Van Aelst. 1996. Rac regulation of actin polymerization and proliferation by a pathway distinct from JUN kinase. Science 274:1374-1376[Abstract/Free Full Text].

30. Karin, M. 1996. The regulation of AP-1 activity by mitogen-activated protein kinases. Philos. Trans. R. Soc. Lond. Ser. B 351:127-134[Medline].

31. Kovary, K., and R. Bravo. 1991. The Jun and Fos protein families are both required for cell cycle progression in fibroblasts. Mol. Cell. Biol. 11:4466-4472[Abstract/Free Full Text].

32. Kozma, R., S. Ahmed, A. Best, and L. Lim. 1995. The Ras-related protein Cdc42Hs and bradykinin promote formation of peripheral actin microspikes and filopodia in Swiss 3T3 fibroblasts. Mol. Cell. Biol. 15:1942-1952[Abstract].

33. Kumar, S., P. C. McDonnell, and P. R. Young. 1997. Novel homologues of CSBP/p38 MAP kinase: activation, substrate specificity and sensitivity to inhibition by pyridinyl imidazoles. Biochem. Biophys. Res. Commun. 235:533-538[Medline].

34. Lamph, W. W., P. Wamsley, P. Sassone-Corsi, and I. M. Verma. 1988. Induction of proto-oncogene JUN/AP-1 by serum and TPA. Nature 334:629-631[Medline].

35. Li, N., A. Batzer, R. Daly, V. Yajnik, E. Skolnik, P. Chardin, D. Bar-Sagi, B. Margolis, and J. Schlessinger. 1993. Guanine-nucleotide-releasing factor hSos1 binds to Grb2 and links receptor tyrosine kinases to Ras signalling. Nature 363:85-88[Medline].

36. Lin, A., A. Minden, H. Martinetto, F. X. Claret, C. Lange-Carter, F. Mercurio, G. L. Johnson, and M. Karin. 1995. Identification of a dual specificity kinase that activates the Jun kinases and p38-Mpk2. Science 268:286-290[Abstract/Free Full Text].

37. Manser, E., T. Leun, H. Salihuddin, L. Tan, and L. Lim. 1993. A non-receptor tyrosine kinase that inhibits the GTPase activity of p21cdc42. Nature 363:364-367[Medline].

38. Manser, E., T. Leung, H. Salihuddin, Z. S. Zhao, and L. Lim. 1994. A brain serine/threonine protein kinase activated by Cdc42 and Rac1. Nature 367:40-46[Medline].

39. Marshall, C. J. 1996. Ras effectors. Curr. Opin. Cell Biol. 8:197-204[Medline].

40. Martin, G. A., G. Bollag, F. McCormick, and A. Abo. 1995. A novel serine kinase activated by rac1/CDC42Hs-dependent autophosphorylation is related to PAK65 and STE20. EMBO J. 14:1970-1978[Medline].

41. Medema, R. H., and J. L. Bos. 1993. The role of p21ras in receptor tyrosine kinase signaling. Crit. Rev. Oncogen. 4:615-661[Medline].

42. Minden, A., A. Lin, M. McMahon, C. Lange-Carter, B. Derijard, R. J. Davis, G. L. Johnson, and M. Karin. 1994. Differential activation of ERK and JNK mitogen-activated protein kinases by Raf-1 and MEKK. Science 266:1719-1723[Abstract/Free Full Text].

43. Minden, A., A. Lin, T. Smeal, B. Derijard, M. Cobb, R. Davis, and M. Karin. 1994. c-Jun N-terminal phosphorylation correlates with activation of the JNK subgroup but not the ERK subgroup of mitogen-activated protein kinases. Mol. Cell. Biol. 14:6683-6688[Abstract/Free Full Text].

44. Minden, A., A. Lin, F. X. Claret, A. Abo, and M. Karin. 1995. Selective activation of the JNK signaling cascade and c-Jun transcriptional activity by the small GTPases Rac and Cdc42Hs. Cell 81:1147-1157[Medline].

45. Molkentin, J. D., and E. N. Olson. 1996. Combinatorial control of muscle development by basic helix-loop-helix and MADS-box transcription factors. Proc. Natl. Acad. Sci. USA 93:9366-9373[Abstract/Free Full Text].

46. Moodie, S. A., B. M. Willumsen, M. J. Weber, and A. Wolfman. 1993. Complexes of Ras.GTP with Raf-1 and mitogen-activated protein kinase kinase. Science 260:1658-1661[Abstract/Free Full Text].

47. Moss, B., O. Elroy-Stein, T. Mizukami, W. A. Alexander, and T. R. Fuerst. 1990. New mammalian expression vectors. Nature 348:91-92[Medline].

48. Nobes, C. D., and A. Hall. 1995. Rho, rac, and cdc42 GTPases regulate the assembly of multimolecular focal complexes associated with actin stress fibers, lamellipodia, and filopodia. Cell 81:53-62[Medline].

49. Ornatsky, O. I., and J. C. McDermott. 1996. MEF2 protein expression, DNA binding specificity and complex composition, and transcriptional activity in muscle and non-muscle cells. J. Biol. Chem. 271:24927-24933[Abstract/Free Full Text].

50. Prywes, R., and R. G. Roeder. 1986. Inducible binding of a factor to the c-fos enhancer. Cell 47:777-784[Medline].

51. Qiu, R., J. Chen, F. McCormick, and M. Symons. 1995. A role for rho in ras transformation. Proc. Natl. Acad. Sci. USA 92:11781-11785[Abstract/Free Full Text].

52. Quantin, B., and R. Breathnach. 1988. Epidermal growth stimulates transcription of the c-jun proto-oncogene in rat fibroblast. Nature 334:538-539[Medline].

53. Ridley, A. J., H. F. Paterson, C. L. Johnston, D. Diekmann, and A. Hall. 1992. The small GTP-binding protein rac regulates growth factor-induced membrane ruffling. Cell 70:401-410[Medline].

54. Rozek, D., and G. P. Pfeifer. 1995. In vivo protein-DNA interactions at the c-jun promoter in quiescent and serum-stimulated fibroblasts. J. Cell. Biochem. 57:479-487[Medline].

55. Ryder, K., and D. Nathans. 1988. Induction of protooncogene c-jun by serum growth factors. Proc. Natl. Acad. Sci. USA 85:8464-8467[Abstract/Free Full Text].

56. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. . Molecular cloning, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

57. Sanchez, I., R. T. Hughes, B. J. Mayer, K. Yee, J. R. Woodgett, J. Avruch, J. M. Kyriakis, and L. I. Zon. 1994. Role of SAPK/ERK kinase-1 in the stress-activated pathway regulating transcription factor c-Jun. Nature 372:794-798[Medline].

58. Smith, S. E., A. G. Papavassiliou, and D. Bohmann. 1993. Different TRE-related elements are distinguished by sets of DNA binding proteins with overlapping sequence specificity. Nucleic Acids Res. 21:1581-1585[Abstract/Free Full Text].

59. Stein, B., H. Brady, M. X. Yang, D. B. Young, and M. S. Barbosa. 1996. Cloning and characterization of MEK6, a novel member of the mitogen-activated protein kinase kinase cascade. J. Biol. Chem. 271:11427-11433[Abstract/Free Full Text].

60. Studier, F. W., A. H. Rosenberg, J. J. Dunn, and J. W. Dubendorff. 1990. Use of T7 RNA polymerase to direct the expression of cloned genes. Methods Enzymol. 185:60-89[Medline].

61. Su, B., E. Jacinto, M. Hibi, T. Kallunki, M. Karin, and Y. Ben-Neriah. 1994. JNK is involved in signal integration during costimulation of T lymphocytes. Cell 77:727-736[Medline].

62. Su, B., and M. Karin. 1996. Mitogen-activated protein kinase cascades and regulation of gene expression. Curr. Opin. Immunol. 8:402-411[Medline].

63. Tan, Y., J. Rouse, A. Zhang, S. Cariati, P. Cohen, and M. J. Comb. 1996. FGF and stress regulate CREB and ATF-1 via a pathway involving p38 MAP kinase and MAPKAP kinase-2. EMBO J. 15:4629-4642[Medline].

64. Treisman, R. 1994. Ternary complex factors: growth factor regulated transcriptional activators. Curr. Opin. Genet. Dev. 4:96-101[Medline].

65. Unlap, T., C. C. Franklin, F. Wagner, and A. S. Kraft. 1992. Upstream regions of the c-jun promoter regulate phorbol ester-induced transcription in U937 leukemic cells. Nucleic Acids Res. 20:897-902[Abstract/Free Full Text].

66. Van Aelst, L., M. Barr, S. Marcus, A. Polverino, and M. Wigler. 1993. Complex formation between RAS and RAF and other protein kinases. Proc. Natl. Acad. Sci. USA 90:6213-6217[Abstract/Free Full Text].

67. Vojtek, A. B., S. M. Hollenberg, and J. A. Cooper. 1993. Mammalian Ras interacts directly with the serine/threonine kinase Raf. Cell 74:205-214[Medline].

68. Whitmarsh, A. J., P. Shore, A. D. Sharrocks, and R. J. Davis. 1995. Integration of MAP kinase signal transduction pathways at the serum response element. Science 269:403-407[Abstract/Free Full Text].

69. Wolfgang, C. D., B. P. C. Chen, J. L. Martindale, N. J. Holbrook, and T. Hai. 1997. Gadd153/Chop10, a potential target gene of the transcriptional repressor ATF3. Mol. Cell. Biol. 17:6700-6707[Abstract].

70. Wu, B., E. J. B. Fodor, R. H. Edwards, and W. J. Rutter. 1989. Nerve growth factor induces the proto-oncogene in PC12 cells. J. Biol. Chem. 264:9000-9003[Abstract/Free Full Text].

71. Xing, J., D. D. Ginty, and M. E. Greenberg. 1996. Coupling of the RAS-MAPK pathway to gene activation by RSK2, a growth factor-regulated CREB kinase. Science 273:959-963[Abstract].

72. Xu, S., D. J. Robbins, L. B. Christerson, J. M. English, C. A. Vanderbilt, and M. H. Cobb. 1996. Cloning of rat MEK kinase 1 cDNA reveals an endogenous membrane-associated 195-kDa protein with a large regulatory domain. Proc. Natl. Acad. Sci. USA 93:5291-5295[Abstract/Free Full Text].

73. Yan, M., T. Dai, J. C. Deak, J. M. Kyriakis, L. I. Zon, and J. R. Woodgett. 1994. Activation of stress-activated protein kinase by MEKK1 phosphorylation of its activator SEK1. Nature 372:798-800[Medline].

74. Zanke, B. W., E. A. Rubie, E. Winnett, J. Chan, S. Randall, M. Parsons, K. Boudreau, M. McInnis, M. Yan, D. J. Templeton, and J. R. Woodgett. 1996. Mammalian mitogen-activated protein kinase pathways are regulated through formation of specific kinase-activator complexes. J. Biol. Chem. 271:29876-29881[Abstract/Free Full Text].

This article has been cited by other articles:

Gregoire, S., Tremblay, A. M., Xiao, L., Yang, Q., Ma, K., Nie, J., Mao, Z., Wu, Z., Giguere, V., Yang, X.-J. (2006). Control of MEF2 Transcriptional Activity by Coordinated Phosphorylation and Sumoylation. J. Biol. Chem. 281: 4423-4433 [Abstract] [Full Text]
Zhang, H., Liu, H., Iles, K. E., Liu, R.-M., Postlethwait, E. M., Laperche, Y., Forman, H. J. (2006). 4-Hydroxynonenal Induces Rat {gamma}-Glutamyl Transpeptidase through Mitogen-Activated Protein Kinase-Mediated Electrophile Response Element/Nuclear Factor Erythroid 2-Related Factor 2 Signaling. Am. J. Respir. Cell Mol. Bio. 34: 174-181 [Abstract] [Full Text]
Bose, C., Zhang, H., Udupa, K. B., Chowdhury, P. (2005). Activation of p-ERK1/2 by nicotine in pancreatic tumor cell line AR42J: effects on proliferation and secretion. Am. J. Physiol. Gastrointest. Liver Physiol. 289: G926-G934 [Abstract] [Full Text]
Nadruz, W. Jr., Corat, M. A.F., Marin, T. M., Guimaraes Pereira, G. A., Franchini, K. G. (2005). Focal adhesion kinase mediates MEF2 and c-Jun activation by stretch: Role in the activation of the cardiac hypertrophic genetic program. Cardiovasc Res 68: 87-97 [Abstract] [Full Text]
Choi, H. S., Choi, B. Y., Cho, Y.-Y., Mizuno, H., Kang, B. S., Bode, A. M., Dong, Z. (2005). Phosphorylation of Histone H3 at Serine 10 Is Indispensable for Neoplastic Cell Transformation. Cancer Res. 65: 5818-5827 [Abstract] [Full Text]
Miralem, T., Hu, Z., Torno, M. D., Lelli, K. M., Maines, M. D. (2005). Small Interference RNA-mediated Gene Silencing of Human Biliverdin Reductase, but Not That of Heme Oxygenase-1, Attenuates Arsenite-mediated Induction of the Oxygenase and Increases Apoptosis in 293A Kidney Cells. J. Biol. Chem. 280: 17084-17092 [Abstract] [Full Text]
Gregoire, S., Yang, X.-J. (2005). Association with Class IIa Histone Deacetylas

1.	Abate, C., D. Luk, and T. Curran. 1990. A ubiquitous nuclear protein stimulates the DNA-binding activity of fos and jun indirectly. Cell Growth Differ. 1:455-462[Abstract].
2.	Angel, P., K. Hattori, T. Smeal, and M. Karin. 1988. The jun proto-oncogene is positively autoregulated by its product, Jun/AP-1. Cell 55:875-885[Medline].
3.	Angel, P., and M. Karin. 1991. The role of Jun, Fos, and the AP-1 complex in cell-proliferation and transformation. Biochim. Biophys. Acta 1072:129-157[Medline].
4.	Benbrook, D. M., and N. C. Jones. 1990. Heterodimer formation between CREB and JUN proteins. Oncogene 5:295-302[Medline].
5.	Bonni, A., D. D. Ginty, H. Dudek, and M. E. Greenberg. 1995. Serine 133-phosphorylated CREB induces transcription via a cooperative mechanism that may confer specificity to neurotrophin signals. Mol. Cell. Neurosci. 6:168-183[Medline].
6.	Brenner, D. A., M. O'Hara, P. Angel, M. Chojkier, and M. Karin. 1989. Prolonged activation of jun and collagenase genes by tumor necrosis factor- $alpha$ . Nature 337:661-663[Medline].
7.	Bruder, J. T., G. Heidecker, and U. R. Rapp. 1992. Serum-, TPA-, and ras-induced expression from Ap-1/Ets-driven promoters requires Raf-1 kinase. Genes Dev. 6:545-556[Abstract/Free Full Text].
8.	Cano, E., C. A. Hazzalin, and L. C. Mahadevan. 1994. Anisomycin-activated protein kinases p45 and p55 but not mitogen-activated protein kinases ERK-1 and -2 are implicated in the induction of c-fos and c-jun. Mol. Cell. Biol. 14:7352-7362[Abstract/Free Full Text].
9.	Chardin, P., J. H. Camonis, N. W. Gale, L. van Aelst, J. Schlessinger, M. H. Wigler, and D. Bar-Sagi. 1993. Human Sos1: a guanine nucleotide exchange factor for Ras that binds to GRB2. Science 260:1338-1343[Abstract/Free Full Text].
10.	Chen, B. P. C., C. D. Wolfgang, and T. Hai. 1996. Analysis of ATF3, a transcription factor induced by physiological stress and modulated by gadd153/Chop10. Mol. Cell. Biol. 16:1157-1168[Abstract].
11.	Coso, O. A., M. Chiariello, J. C. Yu, H. Teramoto, P. Crespo, N. Xu, T. Miki, and J. S. Gutkind. 1995. The small GTP-binding proteins Rac1 and Cdc42 regulate the activity of the JNK/SAPK signaling pathway. Cell 81:1137-1146[Medline].
12.	de Groot, R. P., C. Pals, and W. Kruijer. 1991. Transcriptional control of c-jun by retinoic acid. Nucleic Acids Res. 19:1585-1591[Abstract/Free Full Text].
13.	Derijard, B., J. Raingeaud, T. Barrett, I. H. Wu, J. Han, R. J. Ulevitch, and R. J. Davis. 1995. Independent human MAP-kinase signal transduction pathways defined by MEK and MKK isoforms. Science 267:682-685[Abstract/Free Full Text].
14.	Ginty, D. D., J. M. Kornhauser, M. A. Thompson, H. Bading, K. E. Mayo, J. S. Takahashi, and M. E. Greenberg. 1993. Regulation of CREB phosphorylation in the suprachiasmatic nucleus by light and a circadian clock. Science 260:238-241[Abstract/Free Full Text].
15.	Gonzalez, G. A., and M. R. Montminy. 1989. Cyclic AMP stimulates somatostatin gene transcription by phosphorylation of CREB at serine 133. Cell 59:675-680[Medline].
16.	Gupta, S., D. Campbell, B. Derijard, and R. Davis. 1995. Transcription factor ATF2 regulation by the JNK signal transduction pathway. Science 267:389-393[Abstract/Free Full Text].
17.	Hai, T., F. F. Liu, W. Coukos, and M. Green. 1989. Transcription factor ATF cDNA clones: an extensive family of leucine zipper proteins able to selectively form DNA-binding heterodimers. Genes Dev. 3:2083-2090[Abstract/Free Full Text].
18.	Hai, T., and T. Curran. 1991. Cross-family dimerization of transcription factors Fos/Jun and ATF/CREB alters DNA binding specificity. Proc. Natl. Acad. Sci. USA 88:3720-3724[Abstract/Free Full Text].
19.	Han, J., Y. Jiang, Z. Li, V. V. Kravchenko, and R. J. Ulevitch. 1997. Activation of the transcription factor MEF2C by the MAP kinase p38 in inflammation. Nature 386:296-299[Medline].
20.	Han, T., W. W. Lamph, and R. Prywes. 1992. Mapping of epidermal growth factor-, serum-, and phorbol ester-responsive sequence elements in the c-jun promoter. Mol. Cell. Biol. 12:4472-4477[Abstract/Free Full Text].
21.	Han, T., and R. Prywes. 1995. Regulatory role of MEF2D in serum induction of the c-jun promoter. Mol. Cell. Biol. 15:2907-2915[Abstract].
22.	Herr, I., H. Van Dam, and P. Angel. 1994. Binding of promoter-associated AP-1 is not altered during induction and subsequent repression of the c-jun promoter by TPA and UV irrandiation. Carcinogen 15:1105-1113[Abstract/Free Full Text].
23.	Hibi, M., A. Lin, T. Smeal, A. Minden, and M. Karin. 1993. Identification of an oncoprotein- and UV-responsive protein kinase that binds and potentiates the c-Jun activation domain. Genes Dev. 7:2135-2148[Abstract/Free Full Text].
24.	Hill, C. S., J. Wynne, and R. Treisman. 1995. The Rho family GTPases RhoA, Rac1, and CDC42Hs regulate transcriptional activation by SRF. Cell 81:1159-1170[Medline].
25.	Hu, Q., A. Klippel, A. J. Muslin, W. J. Fantl, and L. T. Williams. 1995. Ras-dependent induction of cellular responses by constitutively active phosphatidylinositol 3-kinase. Science 268:100-102[Abstract/Free Full Text].
26.	Hurst, H. C., N. F. Totty, and N. C. Jones. 1991. Identification and functional characterisation of the cellular activating transcription factor 43 (ATF-43) protein. Nucleic Acids Res. 19:4601-4609[Abstract/Free Full Text].
27.	Iordanov, M., K. Bender, T. Ade, W. Schmid, C. Sachsenmaier, K. Engel, M. Gaestel, H. J. Rahmsdorf, and P. Herrlich. 1997. CREB is activated by UVC through a p38/HOG-1-dependent protein kinase. EMBO J. 16:1009-1022[Medline].
28.	Johansen, F., and R. Prywes. 1994. Two pathways for serum regulation of the c-fos serum response element require specific sequence elements a minimal domain of serum response factor. Mol. Cell. Biol. 14:5920-5928[Abstract/Free Full Text].
29.	Joneson, T., M. McDonough, D. Bar-Sagi, and L. Van Aelst. 1996. Rac regulation of actin polymerization and proliferation by a pathway distinct from JUN kinase. Science 274:1374-1376[Abstract/Free Full Text].
30.	Karin, M. 1996. The regulation of AP-1 activity by mitogen-activated protein kinases. Philos. Trans. R. Soc. Lond. Ser. B 351:127-134[Medline].
31.	Kovary, K., and R. Bravo. 1991. The Jun and Fos protein families are both required for cell cycle progression in fibroblasts. Mol. Cell. Biol. 11:4466-4472[Abstract/Free Full Text].
32.	Kozma, R., S. Ahmed, A. Best, and L. Lim. 1995. The Ras-related protein Cdc42Hs and bradykinin promote formation of peripheral actin microspikes and filopodia in Swiss 3T3 fibroblasts. Mol. Cell. Biol. 15:1942-1952[Abstract].
33.	Kumar, S., P. C. McDonnell, and P. R. Young. 1997. Novel homologues of CSBP/p38 MAP kinase: activation, substrate specificity and sensitivity to inhibition by pyridinyl imidazoles. Biochem. Biophys. Res. Commun. 235:533-538[Medline].
34.	Lamph, W. W., P. Wamsley, P. Sassone-Corsi, and I. M. Verma. 1988. Induction of proto-oncogene JUN/AP-1 by serum and TPA. Nature 334:629-631[Medline].
35.	Li, N., A. Batzer, R. Daly, V. Yajnik, E. Skolnik, P. Chardin, D. Bar-Sagi, B. Margolis, and J. Schlessinger. 1993. Guanine-nucleotide-releasing factor hSos1 binds to Grb2 and links receptor tyrosine kinases to Ras signalling. Nature 363:85-88[Medline].
36.	Lin, A., A. Minden, H. Martinetto, F. X. Claret, C. Lange-Carter, F. Mercurio, G. L. Johnson, and M. Karin. 1995. Identification of a dual specificity kinase that activates the Jun kinases and p38-Mpk2. Science 268:286-290[Abstract/Free Full Text].
37.	Manser, E., T. Leun, H. Salihuddin, L. Tan, and L. Lim. 1993. A non-receptor tyrosine kinase that inhibits the GTPase activity of p21cdc42. Nature 363:364-367[Medline].
38.	Manser, E., T. Leung, H. Salihuddin, Z. S. Zhao, and L. Lim. 1994. A brain serine/threonine protein kinase activated by Cdc42 and Rac1. Nature 367:40-46[Medline].
39.	Marshall, C. J. 1996. Ras effectors. Curr. Opin. Cell Biol. 8:197-204[Medline].
40.	Martin, G. A., G. Bollag, F. McCormick, and A. Abo. 1995. A novel serine kinase activated by rac1/CDC42Hs-dependent autophosphorylation is related to PAK65 and STE20. EMBO J. 14:1970-1978[Medline].
41.	Medema, R. H., and J. L. Bos. 1993. The role of p21ras in receptor tyrosine kinase signaling. Crit. Rev. Oncogen. 4:615-661[Medline].
42.	Minden, A., A. Lin, M. McMahon, C. Lange-Carter, B. Derijard, R. J. Davis, G. L. Johnson, and M. Karin. 1994. Differential activation of ERK and JNK mitogen-activated protein kinases by Raf-1 and MEKK. Science 266:1719-1723[Abstract/Free Full Text].
43.	Minden, A., A. Lin, T. Smeal, B. Derijard, M. Cobb, R. Davis, and M. Karin. 1994. c-Jun N-terminal phosphorylation correlates with activation of the JNK subgroup but not the ERK subgroup of mitogen-activated protein kinases. Mol. Cell. Biol. 14:6683-6688[Abstract/Free Full Text].
44.	Minden, A., A. Lin, F. X. Claret, A. Abo, and M. Karin. 1995. Selective activation of the JNK signaling cascade and c-Jun transcriptional activity by the small GTPases Rac and Cdc42Hs. Cell 81:1147-1157[Medline].
45.	Molkentin, J. D., and E. N. Olson. 1996. Combinatorial control of muscle development by basic helix-loop-helix and MADS-box transcription factors. Proc. Natl. Acad. Sci. USA 93:9366-9373[Abstract/Free Full Text].
46.	Moodie, S. A., B. M. Willumsen, M. J. Weber, and A. Wolfman. 1993. Complexes of Ras.GTP with Raf-1 and mitogen-activated protein kinase kinase. Science 260:1658-1661[Abstract/Free Full Text].
47.	Moss, B., O. Elroy-Stein, T. Mizukami, W. A. Alexander, and T. R. Fuerst. 1990. New mammalian expression vectors. Nature 348:91-92[Medline].
48.	Nobes, C. D., and A. Hall. 1995. Rho, rac, and cdc42 GTPases regulate the assembly of multimolecular focal complexes associated with actin stress fibers, lamellipodia, and filopodia. Cell 81:53-62[Medline].
49.	Ornatsky, O. I., and J. C. McDermott. 1996. MEF2 protein expression, DNA binding specificity and complex composition, and transcriptional activity in muscle and non-muscle cells. J. Biol. Chem. 271:24927-24933[Abstract/Free Full Text].
50.	Prywes, R., and R. G. Roeder. 1986. Inducible binding of a factor to the c-fos enhancer. Cell 47:777-784[Medline].
51.	Qiu, R., J. Chen, F. McCormick, and M. Symons. 1995. A role for rho in ras transformation. Proc. Natl. Acad. Sci. USA 92:11781-11785[Abstract/Free Full Text].
52.	Quantin, B., and R. Breathnach. 1988. Epidermal growth stimulates transcription of the c-jun proto-oncogene in rat fibroblast. Nature 334:538-539[Medline].
53.	Ridley, A. J., H. F. Paterson, C. L. Johnston, D. Diekmann, and A. Hall. 1992. The small GTP-binding protein rac regulates growth factor-induced membrane ruffling. Cell 70:401-410[Medline].
54.	Rozek, D., and G. P. Pfeifer. 1995. In vivo protein-DNA interactions at the c-jun promoter in quiescent and serum-stimulated fibroblasts. J. Cell. Biochem. 57:479-487[Medline].
55.	Ryder, K., and D. Nathans. 1988. Induction of protooncogene c-jun by serum growth factors. Proc. Natl. Acad. Sci. USA 85:8464-8467[Abstract/Free Full Text].
56.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. . Molecular cloning, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
57.	Sanchez, I., R. T. Hughes, B. J. Mayer, K. Yee, J. R. Woodgett, J. Avruch, J. M. Kyriakis, and L. I. Zon. 1994. Role of SAPK/ERK kinase-1 in the stress-activated pathway regulating transcription factor c-Jun. Nature 372:794-798[Medline].
58.	Smith, S. E., A. G. Papavassiliou, and D. Bohmann. 1993. Different TRE-related elements are distinguished by sets of DNA binding proteins with overlapping sequence specificity. Nucleic Acids Res. 21:1581-1585[Abstract/Free Full Text].
59.	Stein, B., H. Brady, M. X. Yang, D. B. Young, and M. S. Barbosa. 1996. Cloning and characterization of MEK6, a novel member of the mitogen-activated protein kinase kinase cascade. J. Biol. Chem. 271:11427-11433[Abstract/Free Full Text].
60.	Studier, F. W., A. H. Rosenberg, J. J. Dunn, and J. W. Dubendorff. 1990. Use of T7 RNA polymerase to direct the expression of cloned genes. Methods Enzymol. 185:60-89[Medline].
61.	Su, B., E. Jacinto, M. Hibi, T. Kallunki, M. Karin, and Y. Ben-Neriah. 1994. JNK is involved in signal integration during costimulation of T lymphocytes. Cell 77:727-736[Medline].
62.	Su, B., and M. Karin. 1996. Mitogen-activated protein kinase cascades and regulation of gene expression. Curr. Opin. Immunol. 8:402-411[Medline].
63.	Tan, Y., J. Rouse, A. Zhang, S. Cariati, P. Cohen, and M. J. Comb. 1996. FGF and stress regulate CREB and ATF-1 via a pathway involving p38 MAP kinase and MAPKAP kinase-2. EMBO J. 15:4629-4642[Medline].
64.	Treisman, R. 1994. Ternary complex factors: growth factor regulated transcriptional activators. Curr. Opin. Genet. Dev. 4:96-101[Medline].
65.	Unlap, T., C. C. Franklin, F. Wagner, and A. S. Kraft. 1992. Upstream regions of the c-jun promoter regulate phorbol ester-induced transcription in U937 leukemic cells. Nucleic Acids Res. 20:897-902[Abstract/Free Full Text].
66.	Van Aelst, L., M. Barr, S. Marcus, A. Polverino, and M. Wigler. 1993. Complex formation between RAS and RAF and other protein kinases. Proc. Natl. Acad. Sci. USA 90:6213-6217[Abstract/Free Full Text].
67.	Vojtek, A. B., S. M. Hollenberg, and J. A. Cooper. 1993. Mammalian Ras interacts directly with the serine/threonine kinase Raf. Cell 74:205-214[Medline].
68.	Whitmarsh, A. J., P. Shore, A. D. Sharrocks, and R. J. Davis. 1995. Integration of MAP kinase signal transduction pathways at the serum response element. Science 269:403-407[Abstract/Free Full Text].
69.	Wolfgang, C. D., B. P. C. Chen, J. L. Martindale, N. J. Holbrook, and T. Hai. 1997. Gadd153/Chop10, a potential target gene of the transcriptional repressor ATF3. Mol. Cell. Biol. 17:6700-6707[Abstract].
70.	Wu, B., E. J. B. Fodor, R. H. Edwards, and W. J. Rutter. 1989. Nerve growth factor induces the proto-oncogene in PC12 cells. J. Biol. Chem. 264:9000-9003[Abstract/Free Full Text].
71.	Xing, J., D. D. Ginty, and M. E. Greenberg. 1996. Coupling of the RAS-MAPK pathway to gene activation by RSK2, a growth factor-regulated CREB kinase. Science 273:959-963[Abstract].
72.	Xu, S., D. J. Robbins, L. B. Christerson, J. M. English, C. A. Vanderbilt, and M. H. Cobb. 1996. Cloning of rat MEK kinase 1 cDNA reveals an endogenous membrane-associated 195-kDa protein with a large regulatory domain. Proc. Natl. Acad. Sci. USA 93:5291-5295[Abstract/Free Full Text].
73.	Yan, M., T. Dai, J. C. Deak, J. M. Kyriakis, L. I. Zon, and J. R. Woodgett. 1994. Activation of stress-activated protein kinase by MEKK1 phosphorylation of its activator SEK1. Nature 372:798-800[Medline].
74.	Zanke, B. W., E. A. Rubie, E. Winnett, J. Chan, S. Randall, M. Parsons, K. Boudreau, M. McInnis, M. Yan, D. J. Templeton, and J. R. Woodgett. 1996. Mammalian mitogen-activated protein kinase pathways are regulated through formation of specific kinase-activator complexes. J. Biol. Chem. 271:29876-29881[Abstract/Free Full Text].