Wild-type ERK2 Research Articles

ERK1/2 Activity Is Critical for the Outcome of Ischemic Stroke.

Ischemic disorders are the leading cause of death worldwide. The extracellular signal-regulated kinases 1 and 2 (ERK1/2) are thought to affect the outcome of ischemic stroke. However, it is under debate whether activation or inhibition of ERK1/2 is beneficial. In this study, we report that the ubiquitous overexpression of wild-type ERK2 in mice (ERK2wt) is detrimental after transient occlusion of the middle cerebral artery (tMCAO), as it led to a massive increase in infarct volume and neurological deficits by increasing blood–brain barrier (BBB) leakiness, inflammation, and the number of apoptotic neurons. To compare ERK1/2 activation and inhibition side-by-side, we also used mice with ubiquitous overexpression of the Raf-kinase inhibitor protein (RKIPwt) and its phosphorylation-deficient mutant RKIPS153A, known inhibitors of the ERK1/2 signaling cascade. RKIPwt and RKIPS153A attenuated ischemia-induced damages, in particular via anti-inflammatory signaling. Taken together, our data suggest that stimulation of the Raf/MEK/ERK1/2-cascade is severely detrimental and its inhibition is rather protective. Thus, a tight control of the ERK1/2 signaling is essential for the outcome in response to ischemic stroke.

Abstract 3648: A high-throughput fluorescence anisotropy screening for discovery of inhibitors that target the D-recruitment site of ERK in vitro and in cells

Abstract Background: Docking sites on mitogen-activated protein kinases (MAPKs) direct protein binding interactions and generate signal specificity. Therapeutically targeting these sites in cancer offers a way to potentially overcome many issues associated with ATP-competitive MAPK inhibitor design, such as high cellular ATP concentrations and highly conserved active sites among MAPKs. Extracellular signal-regulated kinases 1/2 (ERK1/2) are MAPKs that have a pro-tumorigenic role in numerous cancers and possess two protein docking sites that are distinct from the active site: the D-recruitment site (DRS) and F-recruitment site (FRS). In this study, we have developed a high-throughput fluorescence anisotropy screening to identify small molecule inhibitors that target the DRS of ERK. Methods: DRS inhibitors were detected in the high-throughput screening by using fluorescence anisotropy to measure the ability of over 22,000 molecules to competitively displace a fluorescent peptide from the DRS of inactive ERK2. The top 100 compounds from this screening were validated with a secondary radioactive kinase assay. In this assay, the ability of each compound to prevent the phosphorylation of a DRS-specific peptide by active ERK2 was assessed using [γ-32P]-labeled ATP substrate to measure enzyme activity. The top nine compounds were characterized by in vitro dose-response assays against wild-type and C159S ERK2, a DRS mutant. Inhibition of ERK2 phosphorylation of an FRS substrate and JNK2 phosphorylation of c-Jun was evaluated in vitro to determine compound specificity. The potency and specificity of the compounds were also assessed in EGF-stimulated HEK293T cells for their ability to prevent ERK1/2, JNK1/2, and p38α phosphorylation using Western blot. The compounds were tested for irreversible inhibition in vitro through ERK activity tests after exposure to, and subsequent removal of the compounds. Results: Of the nine hit compounds found from the screening, four reversibly inhibited the DRS of ERK2 with in vitro IC50 and Ki values under 5 μM, and did not show significant inhibition of the FRS or C159S ERK2. Two of these compounds also reduced ERK activation to basal levels in MAPK pathway-stimulated HEK293T cells at concentrations of 5 μM. However, in specificity tests these inhibitors demonstrate ability to also target JNK2 and p38α. Conclusions: The fluorescence anisotropy screening developed here can be used to identify potent inhibitors that target the DRS of ERK. These inhibitors can be used to probe ERK signaling events that are mediated by the DRS and can be further optimized to yield highly selective ERK DRS inhibitors with potential therapeutic value. Citation Format: Rachel M. Sammons, Tamer S. Kaoud, Ashwini K. Devkota, Eun J. Cho, Kevin N. Dalby. A high-throughput fluorescence anisotropy screening for discovery of inhibitors that target the D-recruitment site of ERK in vitro and in cells. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 3648. doi:10.1158/1538-7445.AM2015-3648

Abstract 2843: Resistance to ERK inhibitors as a result of an acquired novel P-loop mutation of ERK2

Abstract Genomic aberrations frequently target and activate the MAPK and PI3K pathways in human cancers and combined inhibition of these pathways is being explored widely in the clinic. In a panel of 45 human colorectal cancer cell lines we found the presence of a KRAS mutation resulted in reduced sensitivity to PI3K and MEK inhibitors when used as single treatments. In addition, prolonged exposure to the individual PI3K (GDC-0941) or MEK (GDC-0973) inhibitors resulted in resistance that was associated with acquisition of mutations of the respective pathway being targeted. Resistance to individual targeted agents is challenge in clinic and can be overcome by combining treatments and in our colorectal cancer panel combined MEK/PI3K inhibition exhibited potent synergy in the KRAS mutant lines. However, as with the single treatments prolonged exposure to the combination regime also resulted in resistance through acquisition of a mutation of the allosteric drug-binding site of MEK2 that abrogates binding of the inhibitor. The clinical development of small-molecule ERK inhibitors is of considerable interest as ERK signaling represents a key downstream effector of RAS mutations and ERK inhibitors may retain activity in cells resistant to RAF and MEK inhibitors. Consistent with the latter, the combination resistant line retained sensitivity to an ERK inhibitor (VTX-11e) that also rescued the synergistic interaction when combined with PI3K inhibition. However, prolonged exposure of this MEK/PI3K resistant line to the combination of VTX-11e/GDC0941 resulted in the acquisition of additional resistance to the ERK inhibitor component of the combination. Resistance to VTX-11e was a result of an ERK2 mutation, novel to protein kinases, in a conserved residue of the kinase domain P-loop. Recombinant wild-type and P-loop mutant ERK2 had similar Vmax and ATP Km values, but exhibited a 20-fold increase in IC50 for VTX-11e. Stable expression of the P-loop mutant ERK2 in parent cells resulted in resistance to VTX-11e. Development of an additional VTX-11e resistant line, in this case by prolonged exposure to a single treatment resulted in the acquisition of the same ERK2 mutation. The repeated development of resistance to the MEK/ERK inhibitor arm of the combination is intriguing as the parent cells were not particularly sensitive to treatment with MEK or ERK inhibitors alone, with a GI50 30-fold higher than BRAF mutant cell lines that are sensitive to these inhibitors. Our data show that dual combination of agents, at least for MEK and PI3K pathway inhibition, is insufficient to block the acquisition of resistance, an observation similar to that of clinical trials of BRAF and MEK inhibitors in melanoma. Finally we recommend sequencing of P-loop of the ERKs in clinical studies of ERK inhibitors to determine whether these mutations will occur in the clinic. Citation Format: Paul A. Clarke, Toby Roe, Kate Swabey, Craig McAndrew, Kathy Boxall, Isaac Westwood, Robert van Montfort, Bissan Al-Lazikhani, Paul Workman. Resistance to ERK inhibitors as a result of an acquired novel P-loop mutation of ERK2. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2843. doi:10.1158/1538-7445.AM2015-2843

Radial Spoke Protein 3 Is a Mammalian Protein Kinase A-anchoring Protein That Binds ERK1/2

Initially identified in Chlamydomonas, RSP3 (radial spoke protein 3) is 1 of more than 20 identified radial spoke structural components of motile cilia and is required for axonemal sliding and flagellar motility. The mammalian orthologs for this and other radial spoke proteins, however, remain to be characterized. We found mammalian RSP3 to bind to the MAPK ERK2 through a yeast two-hybrid screen designed to identify interacting proteins that have a higher affinity for the phosphorylated, active form of the protein kinase. Consistent with the screening result, the human homolog, RSPH3, interacts with and is a substrate for ERK1/2. Moreover, RSPH3 is a protein kinase A-anchoring protein (AKAP) that scaffolds the cAMP-dependent protein kinase holoenzyme. The binding of RSPH3 to the regulatory subunits of cAMP-dependent protein kinase, RIIalpha and RIIbeta, is regulated by ERK1/2 activity and phosphorylation. Here we describe an ERK1/2-interacting AKAP and suggest a mechanism by which cAMP-dependent protein kinase-AKAP binding can be modulated by the activity of other enzymes.

Characterization of Mitogen-Activated Protein Kinase (MAPK) Dimers

Phosphorylated ERK2 has an increased capacity to form homodimers relative to unphosphorylated ERK2. We have characterized the nature of the ERK2 dimer and have mutated residues in the crystal dimer interface to examine the impact of dimerization on ERK2 activity. Analysis of the mutants by gel filtration indicates that at least five residues must be mutated simultaneously to produce an ERK2 mutant that is predominantly monomeric. Mutants, whether monomers or dimers, have specific protein kinase activities under fixed assay conditions that are roughly equivalent to wild-type ERK2. The ratio of dimers to monomers is increased as the salt concentration increases, consistent with a strong hydrophobic contribution to the energy of dimer formation. ERK2 dimerization also requires divalent cations. Sedimentation analysis indicates that the related c-Jun N-terminal kinase SAPKalphaI/JNK2 also forms dimers, but dimerization displays no dependence on phosphorylation; the unphosphorylated and phosphorylated forms of the kinase behave similarly, with low micromolar dimer dissociation constants.

Novel protein kinase C-epsilon inhibits human CYP11B2 gene expression through ERK1/2 signalling pathway and JunB

We previously reported that H295R cells co-express three diacylglycerol (DAG)-dependent protein kinase Cs (PKCs), namely conventional (c) PKCalpha and novel (n) PKCepsilon and PKCtheta. The aim of the present work was to evaluate the implication of DAG-dependent PKCs in the activation of p44/42 MAP kinase (MAPK) by angiotensin II (Ang II) and to define the role of this pathway towards CYP11B2 regulation in H295R cells. The PKC inhibitor bisindolylmaleimide 1 (Bis) inhibited Ang II-induced p44/42 MAPK phosphorylation whereas the cPKC inhibitor Gö6976 failed to do so, thus ruling out the participation of PKCalpha. Ang II activated nPKCepsilon and did not affect nPKCtheta, pinpointing PKCepsilon as the mediator of Ang II in p44/42 MAPK activation. Overexpression of wild-type ERK1 and ERK2 significantly reduced basal as well as Ang II-stimulated human -2023CYP11B2-CAT activity; conversely, the two dominant negative mutants increased them. Overexpression of constitutively active (ca) PKCsuppressed Ang II-induced -2023CYP11B2-CAT activity. Infection of H295R cells with adenoviruses (Adv) expressing caPKCepsilon activated endogenous MEK1/2 and p44/42 MAPK. Adv-caPKCepsilon inhibited Ang II-stimulated aldosterone synthase mRNA levels and this action was reversed by the MEK1 inhibitor, PD98059. Also, Ang II increased JunB protein levels and this effect was inhibited by PD98059 and Bis. Adv-caPKCepsilon enhanced JunB protein levels and PD98059 attenuated the increase. JunB overexpression abolished the Ang II-induced promoter activity within -138 bp of the 5'-flanking region of CYP11B2. Collectively, these results demonstrate that PKCepsilon inhibits CYP11B2 transcription through the p44/42 MAPK pathway and JunB in H295R cells.

Transient Versus Sustained Phosphorylation and Nuclear Accumulation of ERKs Underlie Anti-Versus Pro-apoptotic Effects of Estrogens

Sex steroids exert anti-apoptotic effects on osteoblasts/osteocytes but exert pro-apoptotic effects on osteoclasts, in both cases requiring activation of the extracellular signal-regulated kinases (ERKs). To explain the mechanistic basis of this divergence, we searched for differences in the kinetics of phosphorylation and/or in the subcellular localization of ERKs in response to 17beta-estradiol in the two cell types. In contrast to its transient effect on ERK phosphorylation in osteocytic cells (return to base line by 30 min), 17beta-estradiol-induced ERK phosphorylation in osteoclasts was sustained for at least 24 h following exposure to the hormone. Conversion of sustained ERK phosphorylation to transient, by means of cholera toxin-induced activation of the adenylate cyclase/cAMP/protein kinase A pathway, abrogated the pro-apoptotic effect of 17beta-estradiol on osteoclasts. Conversely, prolongation of ERK activation in osteocytes, by means of leptomycin B-induced inhibition of ERK export from the nucleus or overexpression of a green fluorescent protein-ERK2 mutant that resides permanently in the nucleus, converted the anti-apoptotic effect of 17beta-estradiol to a pro-apoptotic one. These findings indicate that the kinetics of ERK phosphorylation and the length of time that phospho-ERKs are retained in the nucleus are responsible for pro-versus anti-apoptotic effects of estrogen on different cell types of bone and perhaps their many other target tissues.

The Death Effector Domain Protein PEA-15 Prevents Nuclear Entry of ERK2 by Inhibiting Required Interactions

ERK2 nuclear-cytoplasmic distribution is regulated in response to hormones and cellular state without the requirement for karyopherin-mediated nuclear import. One proposed mechanism for the movement of ERK2 into the nucleus is through a direct interaction between ERK2 and nucleoporins present in the nuclear pore complex. Previous reports have attributed regulation of ERK2 localization to proteins that activate or deactivate ERK2, such as the mitogen-activated protein (MAP) kinase kinase MEK1 and MAP kinase phosphatases. Recently, a small non-catalytic protein, PEA-15, has also been demonstrated to promote a cytoplasmic ERK2 localization. We found that the MAP kinase insert in ERK2 is required for its interaction with PEA-15. Consistent with its recognition of the MAP kinase insert, PEA-15 blocked activation of ERK2 by MEK1, which also requires the MAP kinase insert to interact productively with ERK2. To determine how PEA-15 influences the localization of ERK2, we used a permeabilized cell system to examine the effect of PEA-15 on the localization of ERK2 and mutants that have lost the ability to bind PEA-15. Wild type ERK2 was unable to enter the nucleus in the presence of an excess of PEA-15; however, ERK2 lacking the MAP kinase insert largely retained the ability to enter the nucleus. Binding assays demonstrated that PEA-15 interfered with the ability of ERK2 to bind to nucleoporins. These results suggest that PEA-15 sequesters ERK2 in the cytoplasm at least in part by interfering with its ability to interact with nucleoporins, presenting a potential paradigm for regulation of ERK2 localization.

Identification of Novel ERK2 Substrates through Use of an Engineered Kinase and ATP Analogs

The mitogen-activated protein kinases are key regulators of cellular organization and function. To understand the mechanisms(s) by which these ubiquitous kinases affect specific cellular changes, it is necessary to identify their diverse and numerous substrates in different cell contexts and compartments. As a first step in achieving this goal, we engineered a mutant ERK2 in which a bulky amino acid residue in the ATP binding site (glutamine 103) is changed to glycine, allowing this mutant to utilize an analog of ATP (cyclopentyl ATP) that cannot be used by wild-type ERK2 or other cellular kinases. The mutation did not inhibit ERK2 kinase activity or substrate specificity in vitro or in vivo. This method allowed us to detect only ERK2-specific phosphorylations within a mixture of proteins. Using this ERK2 mutant/analog pair to phosphorylate ERK2-associated proteins in COS-1 cells, we identified the ubiquitin ligase EDD (E3 identified by differential display) and the nucleoporin Tpr (translocated promoter region) as two novel substrates of ERK2, in addition to the known ERK2 substrate Rsk1. To further validate the method, we present data that confirm that ERK2 phosphorylates EDD in vitro and in vivo. These results not only identify two novel ERK2 substrates but also provide a framework for the future identification of numerous cellular targets of this important signaling cascade.

Two Paths from Ras to ERK

Mitogen-activated protein kinase (MAPK) signaling leads to the activation and nuclear translocation of the terminal kinase in the pathway extracellular signal-regulated kinase (ERK), of which there aretwo isoforms, ERK1 and ERK2. ERKs are activated by phosphorylation by an upstream kinase MEK1 or MEK2. ERK2 mutants that could not bind MEK1 or MEK2 were phosphorylated and activated with similar kinetics and to a similar extent as was wild-type ERK2 when the cells were stimulated with growth factors, suggesting that the basal complex between MEK and ERK2 is not required for signaling through the pathway. However, when the MAPK pathway was activated by expression of a constitutively activated form of MEK1, bypassing the multiple signals that are initiated by an activated growth factor receptor, the MEK-binding mutants of ERK2 were not phosphorylated efficiently. MEK1 could not phosphorylate the ERK2 mutants in vitro either. Inhibition of Ras signaling blocked phosphorylation of the ERK2 mutants in response to growth factors and a constitutively active mutant of Ras stimulated phosphorylation of the mutant ERK2s. Activated forms of Rac and Cdc42 promoted the interaction between wild-type ERK2 and MEK1, but neither of these activated guanosine triphosphatases (GTPases) led to the formation of a detectable complex between the ERK2 mutants and MEK1. Mutation of the two PAK1 phosphorylation sites on MEK1 inhibited Rac-induced MEK1-ERK2 complex formation. MEK2 lacks the consensus PAK1 phosphorylation sites and the interaction between MEK2 and ERK2 is not influenced by activation of Rac. Kinase-defective PAK1 inhibited the MEK1-ERK2 interaction and inhibited ERK2 phosphorylation in response to cell adhesion on fibronectin. Thus, there appears to be a Rac-stimulated interaction, mediated by PAK1 phosphorylation of MEK1, between MEK1 and ERK2 that may explain how signals can converge to activate ERK2 and how MEK1 and MEK2 isoforms may differentially regulate ERK activation. S. T. Eblen, J. K. Slack, M. J. Weber, A. D. Catling, Rac-PAK signaling stimulates extracellular signal-regulated kinase (ERK) activation by regulating formation of MEK1-ERK complexes. Mol. Cell. Biol. 22 , 6023-6033 (2002). [Abstract] [Full Text]

Expression of Human Cystatin A by Keratinocytes Is Positively Regulated via the Ras/MEKK1/MKK7/JNK Signal Transduction Pathway but Negatively Regulated via the Ras/Raf-1/MEK1/ERK Pathway

Cystatin A, a cysteine proteinase inhibitor, is a cornified cell envelope constituent expressed in the upper epidermis. We previously reported that a potent protein kinase C activator, 12-O-tetradecanoylphorbol-13-acetate, increases human cystatin A expression by the activation of AP-1 proteins. Here, we delineate the signaling cascade responsible for this regulation. Co-transfection of the cystatin A promoter into normal human keratinocytes together with a dominant active form of ras increased the promoter activity by 3-fold. In contrast, a dominant negative form of ras suppressed basal cystatin A promoter activity. Further analyses disclosed that transfection of dominant negative forms of raf-1, MEK1, ERK1, ERK2, or wild-type MEKK1 all increased cystatin A promoter activity in normal human keratinocytes, whereas wild-type raf-1, ERK1, ERK2, or dominant negative forms of MEKK1, MKK7, or JNK1 suppressed the promoter activity. The increased or decreased promoter activity reflected the expression of cystatin A on mRNA and protein levels. These effects were not observed when a cystatin A promoter with a T2 (-272 to -278) deletion was used. In contrast, transfection of dominant negative forms of MKK3, MKK4, or p38 did not affect cystatin A promoter activity. Immunohistochemical analyses revealed that phosphorylated active extracellular signal-regulated kinases and c-Jun N-terminal kinase were expressed in the nuclei of basal cells and cells in the suprabasal-granular cell layer, respectively. These results indicate that the expression of cystatin A is regulated via mitogen-activated protein kinase pathways positively by Ras/MEKK1/MKK7/JNK and negatively by Ras/Raf/MEK1/ERK.

Identification of a docking groove on ERK and p38 MAP kinases that regulates the specificity of docking interactions.

MAP kinases (MAPKs) form a complex with MAPK kinases (MAPKKs), MAPK-specific phosphatases (MKPs) and various targets including MAPKAPKs. These docking interactions contribute to regulation of the specificity and efficiency of the enzymatic reactions. We have previously identified a docking site on MAPKs, termed the CD (common docking) domain, which is utilized commonly for docking interactions with MAPKKs, MKPs and MAPKAPKs. However, the CD domain alone does not determine the docking specificity. Here we have identified a novel site on p38 and ERK2 MAPKs that regulates the docking specificity towards MAPKAPKs. Remarkably, exchange of two amino acids in this site of ERK2 for corresponding residues of p38 converted the docking specificity for MAPKAPK-3/3pk, which is a dominant target of p38, from the ERK2 type to the p38 type, and vice versa. Furthermore, our detailed analyses with a number of MAPKAPKs and MKPs suggest that a groove in the steric structure of MAPKs, which comprises the CD domain and the site identified here, serves as a common docking region for various MAPK-interacting molecules.

Novel membrane-targeted ERK1 and ERK2 chimeras which act as dominant negative, isotype-specific mitogen-activated protein kinase inhibitors of Ras-Raf-mediated transcriptional activation of c-fos in NIH 3T3 cells.

Expression of constructs encoding fusion proteins of ERK1 and ERK2 containing a C-terminal farnesylation motif (CAAX) is predominantly localized at the cell membrane and was activated by coexpression of constitutively active Ha-RasL61 and epidermal growth factor. Both fusion proteins significantly inhibit the transcriptional activation of a c-fos-chloramphenicol acetyltransferase reporter induced by RasL61, constitutively active MEK1, or constitutively active RafBXB. The corresponding SAAX chimeras or overexpression of the wild-type ERKs did not interfere with the transcriptional activation of c-fos. The inhibition of the Ras-mediated c-fos induction by ERK2-CAAX can in part be rescued by coexpression of a wild-type ERK2 but not by wild-type ERK1. We find that ERK1-CAAX acts in the same fashion, indicating that mitogen-activated protein kinase (MAPK)-CAAX chimeras interact in an isotype-specific manner. It is demonstrated that both ERK1-CAAX and ERK2-CAAX associate with the corresponding endogenous ERKs, which explains the isotype-specific inhibitory effects of the ERK-CAAX chimeras. Evidence is presented that expression of ERK-CAAX fusion proteins inhibits the nuclear translocation of the corresponding endogenous ERKs. Disruption of MAPK translocation by membrane targeting provides additional, independent proof that nuclear translocation of ERKs is essential for the transcriptional activation of c-fos.

The extracellular-signal-regulated protein kinases (Erks) are required for UV-induced AP-1 activation in JB6 cells.

Mitogen activated protein (MAP) kinase belongs to a large family of serine/threonine protein kinases, including extracellular-signal-regulated protein kinases (Erks), P38 kinase and c-Jun N-terminal kinases (JNKs). Although previous work has shown that both Erks and JNKs are activated in cells in response to ultraviolet (UV) irradiation, most studies have focused only on the role of JNKs in UV-induced AP-1 activation. Hence, the role of Erks in UV-induced AP-1 activity is not well defined. We here have investigated this issue by using MAP kinase kinase (MEK1) inhibitor PD098059 and a dominant negative Erk2, as well as wild-type Erk2, in a JB6 cell model. PD098059 inhibited UVB- or UVC-induced AP-1 activity and phosphorylation of MEK1 and Erks, but not JNKs, in JB6 Cl 41 cells. Overexpression of wild-type Erk2 in Cl 30.7b cells that contain small amounts of Erks caused a 46.6- or 138.1-fold increase of AP-1 activity by UVB and UVC, respectively; introduction of a dominant negative Erk2 into Cl 41 cells significantly blocked the UV-induced Erks activation as well as the AP-1 activation. In contrast, overexpression of wild-type Erk2 in Cl 30.7b cells and dominant negative Erk2 in Cl 41 cells did not show a marked influence on the phosphorylation of JNKs. These results demonstrate that activation of Erks, in addition to the previously reported JNKs, is required for UV-induced AP-1 activation.

A single amino acid substitution makes ERK2 susceptible to pyridinyl imidazole inhibitors of p38 MAP kinase.

Mitogen-activated protein (MAP) kinases are serine/threonine kinases that mediate intracellular signal transduction pathways. Pyridinyl imidazole compounds block pro-inflammatory cytokine production and are specific p38 kinase inhibitors. ERK2 is related to p38 in sequence and structure, but is not inhibited by pyridinyl imidazole inhibitors. Crystal structures of two pyridinyl imidazoles complexed with p38 revealed these compounds bind in the ATP site. Mutagenesis data suggested a single residue difference at threonine 106 between p38 and other MAP kinases is sufficient to confer selectivity of pyridinyl imidazoles. We have changed the equivalent residue in human ERK2, Q105, into threonine and alanine, and substituted four additional ATP binding site residues. The single residue change Q105A in ERK2 enhances the binding of SB202190 at least 25,000-fold compared to wild-type ERK2. We report enzymatic analyses of wild-type ERK2 and the mutant proteins, and the crystal structure of a pyridinyl imidazole, SB203580, bound to an ERK2 pentamutant, I103L, Q105T, D106H, E109G. T110A. These ATP binding site substitutions induce low nanomolar sensitivity to pyridinyl imidazoles. Furthermore, we identified 5-iodotubercidin as a potent ERK2 inhibitor, which may help reveal the role of ERK2 in cell proliferation.

Catalytic activation of extracellular signal-regulated kinases induces cyclin D1 expression in primary tracheal myocytes.

We have demonstrated that extracellular signal-regulated kinases (ERKs) and cyclin D1 are required for bovine tracheal myocyte DNA synthesis. We hypothesized that catalytic activation by ERKs may regulate cyclin D1 expression in these cells. To test this hypothesis, we examined the effects of two inhibitors of ERKs and two reagents that increase the level of activated ERKs on cyclin D1 protein abundance and promoter activity. ERK activity was inhibited either by PD98059, a synthetic inhibitor of mitogen-activated protein kinase (MAPK)/ERK kinase (MEK), the upstream signaling intermediate required and sufficient for ERK activation, or by transient transfection with a dominant-negative mutant of MEK1 (MEK-2A). The level of activated ERKs was increased by transient transfection with either a constitutively active form of MEK1 (MEK-2E) or wild-type ERK2 (MAPKwt). Cyclin D1 expression was assessed either by immunoblot or cotransfection with the full-length cyclin D1 promoter subcloned into a luciferase reporter. We found that pretreatment of bovine tracheal myocytes with PD98059 significantly attenuated platelet- derived growth factor (PDGF)-induced cyclin D1 protein abundance. Furthermore, transfection with MEK-2A reduced PDGF-induced cyclin D1 promoter activity. Finally, transfection with either MEK-2E or MAPKwt induced cyclin D1 promoter activity in the absence of growth factor treatment. We conclude that catalytic activation of ERKs regulates cyclin D1 expression in airway smooth-muscle cells.

Mitogen-activated protein kinase/extracellular signal-regulated kinase 2 regulates cytoskeletal organization and chemotaxis via catalytic and microtubule-specific interactions.

The extracellular signal-regulated kinases (ERKs) 1 and 2 are mitogen-activated protein kinases that act as key components in a signaling cascade linking growth factor receptors to the cytoskeleton and the nucleus. ERK2 mutants have been used to alter cytoskeletal regulation in Chinese hamster ovary cells without affecting cell growth or feedback signaling. Mutation of the unique loop L6 (residues 91-95), which is in a portion of the molecule that is cryptic upon the binding of ERK2 to the microtubules (MTs), generated significant morphological alterations. Most notable phenotypes were observed after expression of a combined mutant incorporating changes to both L6 and the TEY phosphorylation lip, including a 70% increase in cell spreading. Actin stress fibers in these cells, which normally formed a single broad parallel array, were arranged in three or more orientations or in fan-like arrays. MTs, which ordinarily extend longitudinally from the centrosome, spread radially, covering a larger surface area. Single, but not the double, mutations of the Thr and Tyr residues of the TEY phosphorylation lip caused a ca. 25% increase in cell spreading, accompanied by a threefold increase in chemotactic cell migration. Mutation of Lys-52 triggered a 48% increase in cell spreading but no alteration to chemotaxis. These findings suggest that wild-type ERK2 inhibits the organization of the cytoskeleton, the spreading of the cell, and chemotactic migration. This involves control of the orientation of actin and MTs and the positioning of focal adhesions via regulatory interactions that may occur on the MTs.

Mutation of position 52 in ERK2 creates a nonproductive binding mode for adenosine 5'-triphosphate.

Among the protein kinases, an absolutely conserved lysine in subdomain II is required for high catalytic activity. This lysine is known to interact with the substrate ATP, but otherwise its role is not well understood. We have used biochemical and structural methods to investigate the function of this lysine (K52) in phosphoryl transfer reactions catalyzed by the MAP kinase ERK2. The kinetic properties of activated wild-type ERK2 and K52 mutants were examined using the oncoprotein TAL2, myelin basic protein, and a designed synthetic peptide as substrates. The catalytic activities of K52R and K52A ERK2 were lower than that of wild-type ERK2, primarily as a consequence of reductions in kcat. Further, there was little difference in Km for ATP, but the Km,app for peptide substrate was higher for the K52 mutants. The three-dimensional structure of unphosphorylated K52R ERK2 in the absence and presence of bound ATP was determined and compared with the structure of unphosphorylated wild-type ERK2. ATP adopted a well-defined but distinct binding mode in K52R ERK2 compared to the binding mode in the wild-type enzyme. The structural and kinetic data show that mutation of K52 created a nonproductive binding mode for ATP and suggest that K52 is essential for orienting ATP for catalysis.

V-src Induces Prostaglandin Synthase 2 Gene Expression by Activation of the c-Jun N-terminal Kinase and the c-Jun Transcription Factor

A consensus cyclic AMP response element (CRE) in the murine prostaglandin synthase-2 (PGS2) promoter is essential for pgs2 gene expression induced by pp60v-src, the v-src oncogene product. In this study, we investigate (i) the transcription factors active at the PGS2 "CRE site" in response to v-src activation and (ii) the signal transduction pathways by which pp60v-src activates these transcription factors. Transient transfection assays with pgs2 promoter/luciferase reporter chimeric genes suggest that c-Jun mediates v-src-induced pgs2 gene expression. Antibody supershift experiments demonstrate that c-Jun can participate in a complex with the pgs2 promoter CRE site. Moreover, in vitro immuno-complex assays demonstrate that pp60v-src expression strongly activates c-Jun N-terminal kinase (JNK1) enzyme activity. Serines 63 and 73, the sites of c-Jun phosphorylation by JNK, are essential for v-src-induced, pgs2 promoter-mediated luciferase expression. Cotransfection studies with plasmids expressing wild-type JNK, dominant-negative JNK, and dominant-negative MEKK-1 confirm that activation of the Ras/MEKK-1/JNK/c-Jun pathway is required for v-src-induced pgs2 gene expression. Overexpression of either wild-type ERK-1 or ERK-2 proteins also potentiate v-src-mediated luciferase expression driven by the pgs2 promoter, and expression of dominant-negative mutants of ERK-1, ERK-2, or Raf-1 attenuate this response. Thus, in response to v-src expression, a Ras/MEKK-1/JNK signal transduction pathway activating c-Jun and a Ras/Raf-1/ERK pathway converge to mediate pgs2 gene expression via the CRE site in the pgs2 promoter.

The Mitogen-activated Protein Kinase Kinase MEK1 Stimulates a Pattern of Gene Expression Typical of the Hypertrophic Phenotype in Rat Ventricular Cardiomyocytes

Adult mammalian ventricular cardiomyocytes are terminally differentiated cells that enlarge adaptively by hypertrophy. In this situation, genes normally expressed in the fetal ventricular cardiomyocyte (e.g. atrial natriuretic factor (ANF), beta-myosin heavy chain (beta-MHC), and skeletal muscle (SkM) alpha-actin) are re-expressed, and there is transient expression of immediate early genes (e.g. c-fos). Using appropriate reporter plasmids, we studied the effects of transfection of the constitutively active or dominant negative mitogen-activated protein kinase kinase MEK1 on ANF, beta-MHC, and SkM alpha-actin promoter activities in cultured ventricular cardiomyocytes. ANF expression was stimulated (maximally 75-fold) by the hypertrophic agonist phenylephrine in a dose-dependent manner (EC50, 10 microM), and this stimulation was inhibited by dominant negative MEK1. Cotransfection of dominant negative MEK1 with a dominant negative mitogen-activated protein kinase (extracellular signal-regulated protein kinase (ERK2)) increased this inhibition. Transfection with constitutively active MEK1 constructs doubled ANF promoter activity. The additional cotransfection of wild-type ERK2 stimulated ANF promoter activity by about 5-fold. Expression of beta-MHC and SkM alpha-actin was also stimulated. Promoter activity regulated by activator protein-1 or c-fos serum response element consensus sequences was also increased. We conclude that the MEK1/ERK2 cascade may play a role in regulating gene expression during hypertrophy.