Identification and characterization of a new mammalian mitogen-activated protein kinase kinase, MKK2.

Mitogen-activated protein (MAP) kinases are serine/threonine protein kinases activated by dual phosphorylation on threonine and tyrosine residues. A MAP kinase kinase (MKK1 or MEK1) has been identified as a dual-specificity protein kinase that is sufficient to phosphorylate MAP kinases p42mapk and p44mapk on the regulatory threonine and tyrosine residues. Because of the multiplicity of MAP kinase isoforms and the diverse circumstances and agonists leading to their activation, we thought it unlikely that a single MKK could accommodate this complexity. Indeed, two protein bands with MKK activity have previously been identified after renaturation following sodium dodecyl sulfate-polyacrylamide gel electrophoresis. We now report the molecular cloning and characterization of a second rat MAP kinase kinase cDNA, MKK2. MKK2 cDNA contains an open reading frame encoding a protein of 400 amino acids, 7 residues longer than MKK1 (MEK1). The amino acid sequence of MKK2 is 81% identical to that of MKK1, but nucleotide sequence differences occur throughout the aligned MKK2 and MKK1 cDNAs, indicating that MKK2 is the product of a distinct gene. MKK1 and MKK2 mRNAs are expressed differently in rat tissues. Both cDNAs when expressed in COS cells displayed the ability to phosphorylate and activate p42mapk and p44mapk, both MKK1 and MKK2 were activated in vivo in response to serum, and both could be phosphorylated and activated by the v-Raf protein in vitro. However, differences between MKK1 and MKK2 in sites of phosphorylation by proline-directed protein kinases predict differences in feedback regulation.     

In vitro activity of MEKK2 and MEKK3 in detergents is a function of a valine to serine difference in the catalytic domain

MEKK2 and MEKK3 are mitogen-activated protein kinase kinase kinases (MAP3 kinases) of 70 and 71 kDa respectively that are markedly homologous (94%) in their kinase domains. Both MEKK2 and MEKK3 are able to activate the Jun kinase pathway in vivo. However, following routine immunoprecipitation in Triton X-100, MEKK2 but not MEKK3 is able to effectively phosphorylate both SEK-1 and MEK-1 and to undergo autophosphorylation. Unexpectedly, both MEKK2 and MEKK3 are functional in an in vitro kinase assay when cells are solubilized with the closely related detergent, NP-40. Given the high homology between these kinases, we set out to relate this differential sensitivity to Triton X-100 to differences in primary structure. A set of chimeric molecules were generated and the loss of activity in Triton X-100 mapped to kinase domain II/III and specifically to serine 390 of MEKK3 and valine 384 of MEKK2, residues immediately N-terminal to the active site lysine. Mutation of serine 390 of MEKK3 to a valine (as is found in MEKK2) conferred catalytic activity to MEKK3 in Triton X-100 whereas the reciprocal alteration of valine 384 of MEKK2 to a serine conferred lack of activity in Triton X-100 to MEKK2. Search of the protein database identified only three kinases, MEKK3, Pbs2p and Dd-PKI, with a serine or threonine at this site. The presence of a serine or threonine adjacent to the active site lysine in protein kinases is rare and, in MEKK3, results in detergent instability.     

MEK-1 phosphorylation by MEK kinase, Raf, and mitogen-activated protein kinase: analysis of phosphopeptides and regulation of activity.

MEK-1 is a dual threonine and tyrosine recognition kinase that phosphorylates and activates mitogen-activated protein kinase (MAPK). MEK-1 is in turn activated by phosphorylation. Raf and MAPK/extracellular signal-regulated kinase kinase (MEKK) independently phosphorylate and activate MEK-1. Recombinant MEK-1 is also capable of autoactivation. Purified recombinant wild type MEK-1 and a mutant kinase inactive MEK-1 were used as substrates for MEKK, Raf, and autophosphorylation. MEK-1 phosphorylation catalyzed by Raf, MEKK, or autophosphorylation resulted in activation of MEK-1 kinase activity measured by phosphorylation of a mutant kinase inactive MAPK. Phosphoamino acid analysis and peptide mapping identified similar MEK-1 tryptic phosphopeptides after phosphorylation by MEK kinase, Raf, or MEK-1 autophosphorylation. MEK-1 is phosphorylated by MAPK at sites different from that for Raf and MEKK. Phosphorylation of MEK-1 by MAPK does not affect MEK-1 kinase activity. Several phosphorylation sites present in MEK-1 immunoprecipitated from 32P-labeled cells after stimulation with epidermal growth factor were common to the in vitro phosphorylated enzyme. The major site of MAPK phosphorylation in MEK-1 is threonine 292. Mutation of threonine 292 to alanine eliminates 90% of MAPK catalyzed phosphorylation of MEK-1 but does not influence MEK-1 activity. The results demonstrate that MEKK and Raf regulate MEK-1 activity by phosphorylation of common residues and thus, two independent protein kinases converge at MEK-1 to regulate the activity of MAPK.     

B-Raf-dependent regulation of the MEK-1/mitogen-activated protein kinase pathway in PC12 cells and regulation by cyclic AMP.

Growth factor receptor tyrosine kinase regulation of the sequential phosphorylation reactions leading to mitogen-activated protein (MAP) kinase activation in PC12 cells has been investigated. In response to epidermal growth factor, nerve growth factor, and platelet-derived growth factor, B-Raf and Raf-1 are activated, phosphorylate recombinant kinase-inactive MEK-1, and activate wild-type MEK-1. MEK-1 is the dual-specificity protein kinase that selectively phosphorylates MAP kinase on tyrosine and threonine, resulting in MAP kinase activation. B-Raf and Raf-1 are growth factor-regulated Raf family members which regulate MEK-1 and MAP kinase activity in PC12 cells. Protein kinase A activation in response to elevated cyclic AMP (cAMP) levels inhibited B-Raf and Raf-1 stimulation in response to growth factors. Ras.GTP loading in response to epidermal growth factor, nerve growth factor, or platelet-derived growth factor was unaffected by protein kinase A activation. Even though elevated cAMP levels inhibited Raf activation, the growth factor activation of MEK-1 and MAP kinase was unaffected in PC12 cells. The results demonstrate that tyrosine kinase receptor activation of MEK-1 and MAP kinase in PC12 cells is regulated by B-Raf and Raf-1, whose activation is inhibited by protein kinase A, and MEK activators, whose activation is independent of cAMP regulation.     

Deciphering the MAP kinase pathway

MAP kinases (MAPK) are serine/threonine kinases which are activated by a dual phosphorylation on threonine and tyrosine residues. Their specific upstream activators, called MAP kinase kinases (MAPKK), constitute a new family of dual-specific threonine/tyrosine kinases, which in turn are activated by upstream MAP kinase kinase kinases (MAPKKK). These three kinase families are successively stimulated in a cascade of activation described in various species such as mammals, frog, fly, worm or yeast.In mammals, the MAP kinase module lies on the signaling pathway triggered by numerous agonists such as growth factors, hormones, lymphokines, tumor promoters, stress factors, etc. Targets of MAP kinase have been characterize tin all subcellular compartments. In yeast, genetic epistasis helped to characterize the presence of several MAP kinase modules in the same system. By complementation tests, the relationships existing between phylogenetically distant members of each kinase family have been described. The roles of the MAP kinase cascade have been analyzed by engineering various mutations in the kinases of the module. The MAP kinase cascade has thus been implicated in higher eukaryotes in cell growth, cell fate and differentiation, and in low eukaryotes, in conjugation, osmotic stress, cell wall constrct and mitosis.     

Defective regulation of mitogen-activated protein kinase activity in a 3T3 cell variant mitogenically nonresponsive to tetradecanoyl phorbol acetate.

Mitogen-activated protein (MAP) kinase is a serine/threonine-specific protein kinase which is activated in response to various mitogenic agonists (e.g., epidermal growth factor, insulin, and the tumor promoter tetradecanoyl phorbol acetate [TPA]) and requires both threonine and tyrosine phosphorylation for activity. This enzyme has recently been shown to be identical or closely related to pp42, a protein which becomes tyrosine phosphorylated in response to mitogenic stimulation. Neither the kinases which regulate MAP kinase/pp42 nor the in vivo substrates for this enzyme are known. Because MAP MAP kinase is activated and phosphorylated in response both to agents which stimulate tyrosine kinase receptors and to agents which stimulate protein kinase C, a serine/threonine kinase, we have examined the regulation and phosphorylation of this enzyme in 3T3-TNR9 cells, a variant cell line partially defective in protein kinase C-mediated signalling. In this communication, we show that in the 3T3-TNR9 variant cell line, TPA does not cause the characteristically rapid phosphorylation of pp42 or the activation and phosphorylation of MAP kinase. This defective response is not due to the absence of the MAP kinase/pp42 protein itself because both tyrosine phosphorylation of MAP kinase/pp42 and its enzymatic activation could be induced by platelet-derived growth factor in the 3T3-TNR9 cells. Thus, the defect in these variant cells apparently resides in some aspect of the regulation of MAP kinase phosphorylation. Since the 3T3-TNR9 cells are also defective with respect to the TPA-induced increase in ribosomal protein S6 kinase, these in vivo results reinforce the earlier in vitro finding that MAP kinase can regulate S6 kinase activity. These findings suggest a key role for MAP kinase in a kinase cascade cascade involved in the control of cell proliferation.     

MAP kinase kinase from rabbit skeletal muscle. A novel dual specificity enzyme showing homology to yeast protein kinases involved in pheromone-dependent signal transduction.

MAP kinase kinase (MAPKK) was purified 30,000-fold to homogeneity from extracts of rabbit skeletal muscle and shown to be a monomeric protein of apparent molecular mass 44 kDa. MAPKK activated the 42 kDa isoform of MAP kinase by phosphorylation of Thr-183 and Tyr-185, and phosphorylated itself slowly on tyrosine, threonine and serine residues, establishing that it is a 'dual specificity' protein kinase. Peptide sequences from MAPKK were homologous to other protein serine/threonine kinases, especially to the subfamily that includes yeast protein kinases that lie upstream of yeast MAP kinase homologues in the pheromone-dependent mating pathways.     

Nerve growth factor-induced phosphorylation cascade in PC12 pheochromocytoma cells. Association of S6 kinase II with the microtubule-associated protein kinase, ERK1.

Microtubule-associated protein (MAP) kinases form a group of serine/threonine kinases stimulated by various growth factors such as nerve growth factor (NGF) and hormones such as insulin. Interestingly, MAP kinases are thought to participate in a protein kinase cascade leading to cell growth as they have been shown to phosphorylate and activate ribosomal protein S6 kinase. To further evaluate the interactions between the different components of this cascade, we looked at the possible coprecipitation of MAP kinase activator(s) or MAP kinase substrate(s) with MAP kinase. Using antipeptides to the C terminus of the M(r) 44,000 MAP kinase, ERK1, and cell extracts from unstimulated or NGF-treated PC12 cells, we obtained in addition to MAP kinase itself coprecipitation of a protein with a M(r) in the 90,000 range. We further show that this protein is a protein kinase since it becomes phosphorylated on serine residues, after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transfer to a polyvinylidene difluoride membrane. In vitro phosphorylation performed before sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrates NGF-sensitive phosphorylation of this 90-kDa protein on both serine and threonine; the serine phosphorylation is likely to be due to autophosphorylation, and the threonine phosphorylation due to phosphorylation by the copurifying MAP kinase. Furthermore, immunoprecipitation of this 90-kDa protein was obtained with antibodies to S6 kinase II. Finally, using in situ chemical cross-linking, we were able to demonstrate in intact cells the occurrence of an anti-ERK1 immunoreactive species with a molecular mass of approximately 125,000 compatible with a complex between ERK1 and a 90-kDa S6 kinase. Taken together, our observations demonstrate that the 44-kDa MAP kinase is associated, in intact PC12 cells, with a protein kinase which is very likely to be S6 kinase II. In conclusion, our data represent strong evidence for a physiological role of the MAP kinase-S6 kinase cascade in PC12 cells. Finally, our antipeptides provide us with a powerful tool to search for additional physiologically relevant substrates for MAP kinase, a key integrator enzyme for growth factors and hormones.     

Actions of Rho family small G proteins and p21-activated protein kinases on mitogen-activated protein kinase family members.

The mitogen-activated protein (MAP) kinases are a family of serine/threonine kinases that are regulated by distinct extracellular stimuli. The currently known members include extracellular signal-regulated protein kinase 1 (ERK1), ERK2, the c-Jun N-terminal kinase/stress-activated protein kinases (JNK/SAPKs), and p38 MAP kinases. We find that overexpression of the Ste20-related enzymes p21-activated kinase 1 (PAK1) and PAK2 in 293 cells is sufficient to activate JNK/SAPK and to a lesser extent p38 MAP kinase but not ERK2. Rat MAP/ERK kinase kinase 1 can stimulate the activity of each of these MAP kinases. Although neither activated Rac nor the PAKs stimulate ERK2 activity, overexpression of either dominant negative Rac2 or the N-terminal regulatory domain of PAK1 inhibits Ras-mediated activation of ERK2, suggesting a permissive role for Rac in the control of the ERK pathway. Furthermore, constitutively active Rac2, Cdc42hs, and RhoA synergize with an activated form of Raf to increase ERK2 activity. These findings reveal a previously unrecognized connection between Rho family small G proteins and the ERK pathway.     

Recombinant human pim-1 protein exhibits serine/threonine kinase activity.

The protein predicted by the sequence of the human pim-1 proto-oncogene shares extensive homology with known serine/threonine protein kinases, and yet the human Pim-1 enzyme has previously been reported to exhibit protein tyrosine kinase activity both in vitro and in vivo. Recently a new class of protein kinases has been identified which exhibits both protein-serine/threonine and protein-tyrosine kinase activities. We therefore investigated the possibility that the human Pim-1 kinase likewise possesses such bifunctional enzymatic phosphorylating activities. A full-length human pim-1 cDNA was subcloned into the bacterial vector pGEX-2T and the Pim-1 protein expressed as a fusion product with bacterial glutathione S-transferase (GST). The hybrid GST-Pim-1 fusion protein was affinity purified on a glutathione-Sepharose column prior to treatment with thrombin for cleavage of the Pim-1 protein from the transferase. Pim-1 was purified and the identity of recombinant protein confirmed by amino-terminal sequence analysis. Pim-1 was tested for kinase activity with a variety of proteins and peptides known to be substrates for either mammalian protein-serine/threonine or protein-tyrosine kinases and was found to phosphorylate serine/threonine residues exclusively in vitro. Both the Pim-1-GST fusion protein and the isolated Pim-1 protein exhibited only serine/threonine phosphorylating activity under all in vitro conditions tested. Pim-1 phosphorylated purified mammalian histone H1 with a Km of approximately 51 microM. Additionally, Pim-1 exhibited low levels of serine/threonine autophosphorylating activity. These observations place the human Pim-1 in a small select group of cytoplasmic transforming oncogenic kinases, including the protein kinase C, the Raf/Mil, and the Mos subfamilies, exhibiting serine/threonine phosphorylating activity.     

cDNA cloning of MAP kinase kinase reveals kinase cascade pathways in yeasts to vertebrates.

A Xenopus 45 kDa protein has been identified as an immediate upstream factor sufficient for full activation of MAP kinase, and is shown to be capable of undergoing autophosphorylation on serine, threonine and tyrosine residues. In this study, we show that purified 45 kDa protein can phosphorylate a kinase-negative mutant of Xenopus MAP kinase on tyrosine and threonine residues, suggesting that the 45 kDa protein functions as a MAP kinase kinase to activate MAP kinase. We then report the cloning and sequencing of a full-length cDNA encoding this 45 kDa MAP kinase kinase, and show that it is highly homologous to four protein kinases in fission and budding yeasts: byr1, wis1, PBS2 and STE7. These yeast kinases are therefore suggested to function as a direct upstream activator for a presumed MAP kinase homolog in each signal transduction pathway involved in the regulation of cell cycle progression or cellular responses to extracellular signals. Finally, we report bacterial expression of recombinant MAP kinase kinase that can be phosphorylated and activated by Xenopus egg extracts.     

MAP kinase regulation--the oncogene connection

The mitogen-activated protein kinase (MAP kinase) family of cytoplasmic serine/threonine protein kinases is activated by a wide range of extracellular stimuli. In this review we focus on the accumulating evidence that proteins encoded by proto-oncogenes and oncogenes are either involved in the regulation of the MAP kinase pathway or are its targets.     

Growth factors induce nuclear translocation of MAP kinases (p42mapk and p44mapk) but not of their activator MAP kinase kinase (p45mapkk) in fibroblasts

Mitogen-activated protein kinases (p42mapk and p44mapk) are serine/threonine kinases that are activated rapidly in cells stimulated with various extracellular signals. This activation is mediated via MAP kinase kinase (p45mapkk), a dual specificity kinase which phosphorylates two key regulatory threonine and tyrosine residues of MAP kinases. We reported previously that the persistent phase of MAP kinase activation is essential for mitogenically stimulated cells to pass the "restriction point" of the cell cycle. Here, using specific polyclonal antibodies and transfection of epitope-tagged recombinant MAP kinases we demonstrate that these signaling protein kinases undergo distinct spatio-temporal localization in growth factor-stimulated cells. In G0-arrested hamster fibroblasts the activator p45mapkk and MAP kinases (p42mapk, p44mapk) are mainly cytoplasmic. Subsequent to mitogenic stimulation by serum or alpha-thrombin both MAP kinase isoforms translocate into the nucleus. This translocation is rapid (seen in 15 min), persistent (at least during the entire G1 period up to 6 h), reversible (by removal of the mitogenic stimulus) and apparently 'coupled' to the mitogenic potential; it does not occur in response to nonmitogenic agents such as alpha-thrombin-receptor synthetic peptides and phorbol esters that fail to activate MAP kinases persistently. When p42mapk and p44mapk are expressed stably at high levels, they are found in the nucleus of resting cells; this nuclear localization is also apparent with kinase-deficient mutants (p44mapk T192A or Y194F). In marked contrast the p45mapkk activator remains cytoplasmic even during prolonged growth factor stimulation and even after high expression levels achieved by transfection. We propose that the rapid and persistent nuclear transfer of p42mapk and p44mapk during the entire G0-G1 period is crucial for the function of these kinases in mediating the growth response.     

MMK2, a novel alfalfa MAP kinase, specifically complements the yeast MPK1 function

Mitogen-activated protein (MAP) kinases are serine/threonine protein kinases that are activated in response to a variety of stimuli. Here we report the isolation of an alfalfa cDNA encoding a functional MAP kinase, termedMMK2. The predicted amino acid sequence ofMMK2 shares 65% identity with a previously identified alfalfa MAP kinase, termedMMK1. Both alfalfa cDNA clones encode functional kinases when expressed in bacteria, undergoing autophosphorylation and activation to phosphorylate myelin basic protein in vitro. However, only MMK2 was able to phosphorylate a 39 kDa protein from the detergent-resistant cytoskeleton of carrot cells. The distinctiveness ofMMK2 was further shown by complementation analysis of three different MAP kinase-dependent yeast pathways; this revealed a highly specific replacement of the yeastMPK1 (SLT2) kinase byMMK2, which was found to be dependent on activation by the upstream regulators of the pathway. These results establish the existence of MAP kinases with different characteristics in higher plants, suggesting the possibility that they could mediate different cellular responses.     

Nerve growth factor stimulates the activities of the raf-1 and the mitogen-activated protein kinases via the trk protooncogene.

Nerve growth factor (NGF) binds to two structurally unrelated transmembrane proteins on the surface of PC-12 cells, a 75-kDa glycoprotein with a short cytoplasmic sequence, and the trk protooncogene (pp140c-trk), a protein tyrosine kinase activated by NGF. Immediately after binding to cells, NGF induces changes in serine/threonine phosphorylation of several proteins. We have explored the relative roles of these two NGF binding proteins in mediating the activation of two intracellular kinases that may be responsible for some of these phosphorylations. The raf-1 protooncogene is a serine/threonine kinase activated by several growth factors and oncogenic proteins. Treatment of PC-12 cells with NGF increases the serine and threonine phosphorylation of raf-1 in an anti-raf-1 immunoprecipitate kinase assay. This increased phosphorylation observed in vitro is dose-dependent and transient and is accompanied by the NGF-dependent shift in the mobility of immunoblotted raf-1 on SDS sodium dodecyl sulfate-polyacrylamide gel electrophoresis, an effect thought to reflect phosphorylation. NGF-dependent activation of raf-1 is not dependent on protein kinase C, since prolonged exposure to phorbol esters under conditions that cause down-regulation of cellular protein kinase C activity has no effect on the NGF response. Expression of pp140c-trk in 3T3 fibroblasts (3T3-c-trk), as evidenced by cross-linking of 125I-NGF to the 140-kDa protein, permits the NGF-dependent activation of raf-1 kinase, detected in the immunoprecipitate kinase assay, anti-raf immunoblot shift on gel electrophoresis, and incorporation of [32P]orthophosphate into the raf-1 protein. The concentration dependence of raf-1 activation is identical in 3T3-c-trk and PC-12 cells, despite the absence of the 75-kDa NGF binding protein in 3T3-c-trk cells. NGF is without effect in untransfected 3T3 cells or in Chinese hamster ovary cells overexpressing p75, although raf-1 is present in these cells. Similarly, the NGF-dependent activation of mitogen-activated protein (MAP) kinase is detected in 3T3-c-trk cells, but not in untransfected 3T3 or Chinese hamster ovary cells overexpressing p75. As described for raf-1 activation, the NGF dose responses for MAP kinase activation in 3T3-c-trk and PC-12 cells are virtually superimposable. These data indicate that the activation of these two serine/threonine kinases by NGF is mediated solely by binding to and activating the pp140c-trk receptor.     

Xenopus MAP kinase activator is a serine/threonine/tyrosine kinase activated by threonine phosphorylation.

Xenopus MAP kinase activator, a 45 kDa protein, has been shown to function as a direct upstream factor sufficient for full activation and both tyrosine and serine/threonine phosphorylation of inactive MAP kinase. We have now shown by using an anti-MAP kinase activator antiserum that MAP kinase activator is ubiquitous in tissues and is regulated post-translationally. Activation of MAP kinase activator is correlated precisely with its threonine phosphorylation during the oocyte maturation process. It is a key question whether MAP kinase activator is a kinase or not. We have shown that Xenopus MAP kinase activator purified from mature oocytes is capable of undergoing autophosphorylation on serine, threonine and tyrosine residues. Dephosphorylation of purified activator by protein phosphatase 2A treatment inactivates its autophosphorylation activity as well as its activator activity. Thus, Xenopus MAP kinase activator is a protein kinase with specificity for both serine/threonine and tyrosine. Partial protein sequencing of purified activator indicates that it contains a sequence homologous to kinase subdomains VI and VII of two yeast protein kinases, STE7 and byrl.