Identification of multiple epidermal growth factor-stimulated protein serine/threonine kinases from Swiss 3T3 cells

How does the G protein, Gi2, transduce mitogenic signals?

Serpentine receptors coupled to the heterotrimeric G protein, Gi2, are capable of stimulating DNA synthesis in a variety of cell types. A common feature of the Gi2-coupled stimulation of DNA synthesis is the activation of the mitogen-activated protein kinases (MAPKs). The regulation of MAPK activation by the Gi2-coupled thrombin and acetylcholine muscarinic M2 receptors occurs by a sequential activation of a network of protein kinases. The MAPK kinase (MEK) which phosphorylates and activates MAPK is also activated by phosphorylation. MEK is phosphorylated and activated by either Raf or MEK kinase (MEKK). Thus, Raf and MEKK converge at MEK to regulate MAPK. Gi2-coupled receptors are capable of activating MEK and MAPK by Raf-dependent and Raf-independent mechanisms. Pertussis toxin catalyzed ADP-ribosylation of alpha i2 inhibits both the Raf-dependent and -independent pathways activated by Gi2-coupled receptors. The Raf-dependent pathway involves Ras activation, while the Raf-independent activation of MEK and MAPK does not involve Ras. The Raf-independent activation of MEK and MAPK most likely involves the activation of MEKK. The vertebrate MEKK is homologous to the Ste11 and Byr2 protein kinases in the yeast Saccharomyces cerevisiae and Schizosaccharomyces pombe, respectively. The yeast Ste11 and Byr2 protein kinases are involved in signal transduction cascades initiated by pheromone receptors having a 7 membrane spanning serpentine structure coupled to G proteins. MEKK appears to be conserved in the regulation of G protein-coupled signal pathways in yeast and vertebrates. Raf represents a divergence in vertebrates from the yeast pheromone-responsive protein kinase system.(ABSTRACT TRUNCATED AT 250 WORDS)

Signal transduction pathways involving the Raf proto-oncogene

The raf genes encode for a family of cytoplasmic proteins (A-raf, B-raf and c-raf-1) with associated serine/threonine kinase activities. Raf-1 is an important mediator of signals involving cell growth, transformation and differentiation. It is activated in response to a wide variety of extracellular stimuli such as insulin, nerve growth factor (NGF), platelet derived-growth factor (PDGF), and in response to expression of oncogenes, v-src and v-ras, in a cell-specific manner. Recently, the first physiological substrate for Raf-1 protein kinase was identified. Raf-1 was found to phosphorylate and activate Mitogen-Activated Protein Kinase Kinase (MEK), an activator of MAP kinase, thus linking the Raf-1 signaling pathway with that of MAP kinase. Cell specific differences in signalling pathways involving Raf-1 and MAP kinase have also been discovered. Accumulating evidence indicates that membrane tyrosine kinases, ras, Raf-1, MEK and MAP kinase are interconnected via a complex network rather than via a linear pathway involving multiple substrates and feedback loops.

MAP kinase cascade in astrocytes

We have studied in cultured rat astroglial cells MAP kinases, known for their role in intracellular signal transduction. The MAP kinase activity was stimulated by growth factors (FGFb, FGFa, EGF, PDGF, and IGF1), by a phorbol ester (TPA) activating-protein kinase C (PKC), by a neuropeptide (endothelin-1), and by a neuromediator (carbachol). Astrocytes pretreated for 18 h with TPA were still stimulated by growth factors and endothelin, suggesting that down-regulated isoforms of PKC are not involved in MAP kinase activation. In contrast, the small effect of carbachol was suppressed by TPA pretreatment. Astrocytes contained two proteins (p41 and p44) recognized by MAP kinase antibody. These proteins were phosphorylated on tyrosine residues in the cytosols of stimulated astrocytes. The kinetics of MAP kinase activation by FGFb and IGF1 were very different. FGFb promoted a rapid activation of MAP kinase (about 10 min) plus a prolonged phase that lasted at least 12 h. IGF1 produced only a rapid transient peak of activation at about 20 min. Hence, extracellular signals might generate different effects in astrocytes by differentially modulating the MAP kinase cascade. On a Mono Q column the growth factor-stimulated MAP kinase activity was separated into two peaks containing p41 and p44. Stimulation of astrocytes altered the elution pattern of p44 as a result of its phosphorylation. An ATP-dependent MAP kinase activator (MW = 40-45 kDa) was found in fractions of FGFb-stimulated cells which were not retained on Mono Q column, indicating the existence of a MAP kinase kinase (MEK) in astrocytes. C-Raf, identified in other cells as a MAP kinase kinase kinase, was also present in astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

S6 phosphorylation and the p70s6k/p85s6k

Activation of cell growth leads to the multiple phosphorylation of 40S ribosomal protein S6. The kinase responsible for controling this event is termed p70s6k/p85s6k. Both isoforms of the kinase are derived from a common gene activated by a complex set of phosphorylation events; each resides in a unique cellular compartment: the p70s6k in the cytoplasm and the p85s6k in the nucleus. Although p70s6k/p85s6k represent the first mitogen-activated serine/threonine kinase described, the signaling pathway leading to activation of both isoforms remains obscure. Recent studies have shown that this pathway is distinct from that of p21ras and the p42mapk/p44mapk, and that bifurcation of these pathways takes place at the level of the receptor. Experiments with point mutants of the PDGF receptor and inhibitors of phosphatidyl-inositol-3-OH kinase have implicated the latter molecule in this signaling event, but more recent findings suggest an alternative route may be employed. The p70s6k signaling pathway can also be ablated by the immunosuppressant rapamycin, which blocks p70s6k activation and S6 phosphorylation without affecting the other kinases whose activation is triggered by mitogen treatment. In parallel, rapamycin suppresses the translation of a family of mRNAs that contain a polypyrimidine tract at their 5' transcriptional start site. The implication is that this event is mediated by the phosphorylated form of S6 that may either (1) directly interact with the polypyrimidine tract or (2) alter the affinity of the 40S ribosome mRNA binding site for polypyrimidine tract mRNAs, or (3) recognize proteins that directly bind to the polypyrimidine tract.

Phosphorylation of tau protein in tau-transfected 3T3 cells

The tau protein of Alzheimer paired helical filaments (PHFs) is aberrantly phosphorylated, as evidenced by its reactivity with several phosphate-dependent antibodies. We sought to identify whether this unusual phosphorylation state exists in tau expressed by transfected NIH 3T3 fibroblasts. Immunoblot analysis of cell clones transfected with constructs for either the 3-repeat or 4-repeat isoforms of tau revealed two tau bands, with the lower band migrating with unmodified tau in each case. Antibodies T3P and tau-1 were used to probe these bands, as they also react with PHF-tau in a phosphate-dependent manner. The epitopes for both antibodies were phosphorylated in both tau isoforms. Only the upper band was phosphorylated at the T3P site whereas phosphorylation at the tau-1 site was not always associated with a shift of tau mobility on gels. Tau in both bands was soluble, in contrast to PHF-tau, and was competent to bind to exogenously added bovine microtubules. Colchicine treatment of the cells resulted in an inhibition of phosphorylation at both sites, through an unknown mechanism. In conclusion human tau expressed in 3T3 cells was phosphorylated at the T3P and tau-1 sites as is PHF-tau, although no PHFs formed and the phosphorylated tau was competent to bind to microtubules.

The MAP kinase cascade. Discovery of a new signal transduction pathway

Using biochemical techniques similar to those used by Krebs and Fischer in elucidating the cAMP kinase cascade, a protein kinase cascade has been found that represents a new pathway for signal transduction. This pathway is activated in almost all cells that have been examined by many different growth and differentiation factors, suggesting control of different cell responses. At this writing, four tiers of growth factor regulated kinases, each tier represented by more than one enzyme, have been reconstituted in vitro to form the MAP kinase cascade. Preliminary findings suggesting multiple feedback or feedforward regulation of several components in the cascade predict higher complexity than a simple linear pathway.

Casein kinase II in signal transduction and cell cycle regulation

Casein kinase II is a protein serine/threonine kinase that is ubiquitously distributed in eukaryotes. Molecular cloning studies and protein sequence analysis of purified proteins have demonstrated the existence of two related, but distinct, isoenzymic forms of its catalytic subunit in mammals and birds. At present, the precise role of the individual casein kinase II isoforms in biological responses is poorly understood. However, a great deal of evidence indicates that casein kinase II is an important component of signalling pathways that control the growth and division of cells. In particular, casein kinase II is known to phosphorylate, and in several cases, regulate the activity of a variety of regulatory nuclear proteins including nuclear oncoproteins, transcription factors, and enzymes involved in other aspects of DNA metabolism. In this review, we will summarize evidence relating to the involvement of casein kinase II in signal transduction events that are relevant to cell proliferation.

Phosphorylation and activation of human tyrosine hydroxylase in vitro by mitogen-activated protein (MAP) kinase and MAP-kinase-activated kinases 1 and 2

Mitogen-activated protein-kinase (MAP) kinase-activated protein kinases 1 and 2 (MAPKAP kinase-1, MAPKAP kinase-2), were found to phosphorylate bacterially expressed human tyrosine hydroxylase in vitro at comparable rates to other proteins thought to be physiological substrates of these protein kinases. The phosphorylation of all four alternatively spliced forms of human tyrosine hydroxylase by MAPKAP kinases-1 and -2 reached plateau values at 1 mol/mol subunit and 2 mol/mol subunit, respectively; the sites of phosphorylation were identified as Ser40 (MAPKAP kinase-1) and Ser19 and Ser40 (MAPKAP kinase-2). In contrast to calmodulin-dependent protein kinase-II, which phosphorylates Ser19 faster than Ser40, MAPKAP kinase-2 phosphorylated Ser40 about twice as fast as Ser19. The maximal activation of tyrosine hydroxylase by MAPKAP kinase-1 or-2 was about 3-fold, and activation by MAPKAP kinases-1 and -2 or calmodulin-dependent protein kinase-II correlated with the extent of phosphorylation of Ser40. The four alternatively spliced forms of human tyrosine hydroxylase were phosphorylated at Ser31 by MAP kinase, but at markedly different rates (3 = 4 > 1 >> 2). Forms 3 and 4 were phosphorylated rapidly and stoichiometrically by MAP kinase doubling the activity, while phosphorylation of form 1 by MAP kinase to 0.4 mol/mol subunit increased activity by 40%. The effect on activity of phosphorylating both Ser31 and Ser40 was not additive. The possible roles of MAPKAP kinase-1, MAPKAP kinase-2 and MAP kinase in the regulation of tyrosine hydroxylase in vivo are discussed.

The regional distribution of extracellularly regulated kinase-1 and -2 messenger RNA in the adult rat central nervous system

It has previously been shown that an intracellular serine/threonine kinase known as extracellularly signal-regulated kinase, also known as microtubule-associated protein kinase, is phosphorylated and activated in response to a range of hormones, growth factors (e.g. nerve growth factor) and neurotransmitters (e.g. N-methyl-D-aspartate) in a variety of cells including neurons. Extracellularly regulated kinases phosphorylate transcription factors, cytoskeletal proteins and enzyme targets. As such they are believed to function in neuronal signal transduction. In situ hybridization histochemistry using synthetic oligonucleotide probes has been used to identify cells in the adult rat central nervous system containing messenger RNAs coding for two isoforms of extracellularly regulated kinase. Extracellularly regulated kinase-2 messenger RNA was observed in many regions including the cerebral cortex, olfactory bulb, hippocampus, amygdala, basal ganglia (except the globus pallidus and endopeduncular nucleus), basal nucleus, thalamus, hypothalamus, brain stem nuclei, cerebellum and neurons in the spinal cord. Extracellularly regulated kinase-1 messenger RNA was confined to fewer regions than extracellularly regulated kinase-2 messenger RNA. Hybridization signals for extracellularly regulated kinase-1 were seen in the olfactory bulb, cortex, regions of the hippocampus, amygdala, nucleus basalis of Maynert, substantia nigra, some hypothalamic and brainstem nuclei and cerebellum, as well as neurons of the spinal cord. Of particular interest, extracellularly regulated kinase-1 messenger RNA was absent from all regions of the basal ganglia and thalamus. Furthermore, extracellularly regulated kinase-1 was almost absent from the CA1 region, whereas extracellularly regulated kinase-2 was present in all neurons of the hippocampus. There were no CNS regions that expressed extracellularly regulated kinase-1 but not extracellularly regulated kinase-2; however, neurons of the dorsal root ganglia showed extracellularly regulated kinase-1 but not extracellularly regulated kinase-2 messenger RNA. Although extracellularly regulated kinase-1 and extracellularly regulated kinase-2 expression was selectively neuronal in the brain, extracellularly regulated kinase-1 messenger RNA was localized to glia in the spinal cord. The distinct cellular distribution of individual extracellularly regulated kinases in the adult rat CNS suggests that they play unique signalling roles.

Activation of mitogen-activated protein kinase by epidermal growth factor in hippocampal neurons and neuronal cell lines

Epidermal growth factor (EGF) functions in a bimodal capacity in the nervous system, acting as a mitogen in neuronal stem cells and a neurotrophic factor in differentiated adult neurons. Thus, it is likely that EGF signal transduction, as well as receptor expression, differs among various cell types and possibly in the same cell type at different stages of development. We used hippocampal neuronal cell lines capable of terminal differentiation to investigate changes in EGF receptor expression, DNA synthesis, and stimulation of mitogen-activated protein (MAP) kinase by EGF before and after differentiation. H19-7, the line that was most representative of hippocampal neurons, was mitogenically responsive to EGF only before differentiation and increased in EGF binding after differentiation. MAP kinase was stimulated by EGF in both undifferentiated and differentiated cells, as well as in primary hippocampal cultures treated with either EGF or glutamate. These results indicate that the activation of MAP kinase by EGF is an early signaling event in both mitotic and postmitotic neuronal cells. Furthermore, these studies demonstrate the usefulness of hippocampal cell lines as a homogeneous neuronal system for studies of EGF signaling or other receptor signaling mechanisms in the brain.

Insulin receptor serine kinase activation by casein kinase 2 and a membrane tyrosine kinase

The insulin receptor (IR) tyrosine kinase can apparently directly phosphorylate and activate one or more serine kinases. The identities of such serine kinases and their modes of activation are still unclear. We have described a serine kinase (here designated insulin receptor serine (IRS) kinase) from rat liver membranes that co-purifies with IR on wheat germ agglutinin-agarose. The kinase was activated after phosphorylation of the membrane glycoproteins by casein kinase-1, casein kinase-2, or casein kinase-3 (Biochem Biophys Res Commun 171: 75-83,1990). In this study, IRS kinase was further characterized. The presence of vanadate or phosphotyrosine in reaction mixtures was required for activation to be observed. Phosphoserine and phosphothreonine are only about 25% as effective as phosphotyrosine, whereas sodium fluoride and molybdate were ineffective in supporting activation. Vanadate and phosphotyrosine support IRS kinase activation by apparently inhibiting phosphotyrosine protein phosphatases present among the membrane glycoproteins. IR beta-subunit, myelin basic protein, and microtubule-associated protein-2 are good substrates for IRS kinase. The kinase prefers Mn2+ (Ka = 1.3 mM) as a metal cofactor. Mg2+ (Ka = 3.3 mM) is only 30% as effective as Mn2+. The kinase activity is stimulated by basic polypeptides, with greater than 30-fold activation achieved with polylysine and protamine. Our results suggest that both serine/threonine and tyrosine phosphorylation are required for activation of IRS kinase. Serine phosphorylation is catalyzed by one of the casein kinases, whereas tyrosine phosphorylation is catalyzed by a membrane tyrosine kinase, possibly IR tyrosine kinase.

cPLA2 is phosphorylated and activated by MAP kinase

Treatment of cells with agents that stimulate the release of arachidonic acid causes increased serine phosphorylation and activation of cytosolic phospholipase A2 (cPLA2). Here we report that cPLA2 is a substrate for mitogen-activated protein (MAP) kinase. Moreover, phosphorylation by MAP kinase increases the enzymatic activity of cPLA2. The site of cPLA2 phosphorylation by MAP kinase, Ser-505, is identical to the major site of cPLA2 phosphorylation observed in phorbol ester-treated cells. Replacement of Ser-505 with Ala resulted in a mutant cPLA2 that is not a substrate for MAP kinase and causes little or no enhanced agonist-stimulated arachidonate release from intact cells. Taken together, these data indicate that MAP kinase mediates, at least in part, the agonist-induced activation of cPLA2.

Early responses in mitogenic signaling, bombesin induced protein phosphorylations in Swiss 3T3 cells

The amphibian tetradecapeptide bombesin as well as the bombesin-related mammalian peptides are potent mitogens for Swiss 3T3 cells. Other sole mitogens for Swiss 3T3 cells, such as PDGF and FGF, invariably signal through a tyrosine kinase receptor. The bombesin receptor has been cloned from Swiss 3T3 fibroblasts and was shown to be a member of the family of G-protein-linked neuropeptide receptors, whose sequence does not reveal a protein kinase domain. Upon binding to its receptor, bombesin evokes a complex cascade of early biochemical events including inositol 1,4,5-trisphosphate-induced mobilization of intracellular Ca2+, Na+ and K+ fluxes, PK-C activation, transmodulation of the EGF-receptor, accumulation and expression of the proto-oncogenes c-fos and c-myc and cAMP production. The intermediates in this signaling pathway are still largely unknown. Since many hormones and neuropeptides that signal through similar receptors with seven membrane spanning domains are by themselves not mitogenic for Swiss 3T3 fibroblasts, we suggest that bombesin acts through a rather special signaling pathway. Although its receptor does not feature a cytoplasmic tyrosine kinase domain, bombesin rapidly stimulates the tyrosine phosphorylation of multiple protein substrates, which are however quite distinct from the usual targets of tyrosine kinase receptors. Yet, a similar cascade of Ser/Thr protein kinases is activated downstream of these differentiating tyrosine kinase events, since, like EGF or insulin, bombesin rapidly stimulates the activity of two MBP kinases as well as several S6 peptide kinases. The present report furthermore implicates CK-2 in the early signal transduction pathway of this mitogen, and it is postulated that the activation of CK-2 may be an intrinsic property of "sole mitogens" like bombesin, as it may be a compulsory event leading to cell division. In that respect, CK-2 may also be the point of integration of multiple signaling pathways, initiated by several different growth factors which by their synergistic actions make cell proliferation possible.

Casein kinases: pleiotropic mediators of cellular regulation

The present review on casein kinases focuses mainly on the possible metabolic role of CK-2, with special emphasis on its behavior in pathological tissues. From these data at least three ways to regulate CK-2 activity emerge: (i) CK-2 activity changes during embryogenesis, being high at certain stages of development and showing basal activity values at others; (ii) CK-2 activity can be enhanced in vitro by treatment of tissue culture cells with various growth factors and serum and (iii) CK-2 activity is constitutively enhanced in rapidly proliferating cells. The regulated CK-2 activity changes during embryogenesis cannot be explained as yet. In the case of the constitutive high expression of CK-2 in tumors, genetic changes may be responsible, e.g. through alterations of the regulatory genetic elements and/or regulation by specific transcription factors. In the case of serum induction, no genetic changes are necessarily involved; the observed changes may be entirely due to a signal transduction pathway where CK-2 could be phosphorylated by another kinase(s). CK-2 cDNAs from various organisms have been isolated and characterized. From the deduced amino acid sequence it turns out that CK-2 subunits are highly conserved during evolution. The relationship between CK-2 alpha from humans and plants is still 73%. Similar relationships are reported for the beta-subunit. Chromosomal assignment of CK-2 alpha shows two gene loci, one of which is a pseudogene. They are located on different chromosomes. Expression of the CK-2 subunits in Escherichia coli and the Baculo expression system is shown. The recombinant subunits can self-assemble to a functional holoenzyme in vitro. Biochemical and biophysical analysis of the recombinant beta-subunit suggests it to be trifunctional in association with the alpha-subunit affecting: (i) stability, (ii) enzyme specificity and (iii) enzyme activity. The question where CK-2 and its subunits are located throughout the cell cycle has also been addressed, mainly because of the large discrepancies that still exist between results obtained by different investigators. Tissue-specific expression of CK-2 at the mRNA and at the protein level has also been given attention. The fact that the enzyme activity is surprisingly high in brain and low in heart and lung may be indicative of involvement of CK-2 in processes other than proliferation.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence that MAP (mitogen-activated protein) kinase activation may be a necessary but not sufficient signal for a restricted subset of responses in IL-1-treated epidermoid cells

We have investigated the activation of mitogen-activated protein kinase (MAP-kinase) in KB human epidermoid carcinoma cells treated with interleukin 1 (IL-1). MAP-kinase activity was transient; the time required for activity to reach a maximal level was dependent upon the dose of IL-1, ranging from 15 minutes to 45 minutes. The level of kinase induction correlated well with dose-response curves for two characteristic IL-1-induced responses, PGE2 and IL-6 production. MAP-kinase activity returned to basal levels within 2 hours regardless of the amount of IL-1 added to the system. Exposure of KB cells to free IL-1 was accordingly restricted to periods of 2 hours or less, by replacing IL-1 with an excess of IL-1 receptor antagonist. Even after 2 hours exposure, the ability of IL-1 to induce IL-6 or PGE2 was still IL-1ra-inhibitable by more than 80%, suggesting that events downstream of, or parallel to MAP-kinase activation, requiring the continual formation of new IL-1 receptor complexes, are needed to fully elicit these responses. Two general serine/threonine kinase inhibitors, K252a and quercetin, were found to strongly inhibit MAP kinase in vivo with ED50s of c. 100 nM and 30 microM, respectively. At these concentrations, both compounds effectively inhibited IL-1-driven PGE2 and IL-6 induction without affecting general protein synthesis or secretion. Other non-selective kinase inhibitors had less effect on MAP-kinase activation or IL-1-induced biological responses. The transient activation of MAP-kinase induction correlated strikingly with activation of the transcription factor NF-kappa B. IL-1-induced NF-kappa B activation was, however, relatively insensitive to inhibition by K252a or quercetin. We suggest that MAP-kinase is likely to be a necessary, but not sufficient, intermediate in some (IL-6, PGE2 induction) but not all (NF-kappa B activation) IL-1 responses in these cells.

Identification and endothelin-induced activation of multiple extracellular signal-regulated kinases in aortic smooth muscle cells

In order to explore intracellular signaling pathways of the mitogenic action of endothelin (ET), we examined the effect of ET on activities of extracellular signal-regulated kinases (ERKs) in rat aortic smooth muscle cells (SMCs). Treatment of rat aortic SMCs with ET-1 increased kinase activities toward myelin basic protein (MBP). Both 43- and 41-kDa proteins were activated when kinase assays were done in MBP-containing polyacrylamide gels after SDS-PAGE. These proteins were identified as ERK1 and ERK2 with immunoprecipitation and immunoblotting using antipeptide antibodies, respectively. These results indicate that ERKs mediate signal transduction by ET.

Intracellular signaling by hydrolysis of phospholipids and activation of protein kinase C

Hydrolysis of inositol phospholipids by phospholipase C is initiated by either receptor stimulation or opening of Ca2+ channels. This was once thought to be the sole mechanism to produce the diacylglycerol that links extracellular signals to intracellular events through activation of protein kinase C. It is becoming clear that agonist-induced hydrolysis of other membrane phospholipids, particularly choline phospholipids, by phospholipase D and phospholipase A2 may also take part in cell signaling. The products of hydrolysis of these phospholipids may enhance and prolong the activation of protein kinase C. Such prolonged activation of protein kinase C is essential for long-term cellular responses such as cell proliferation and differentiation.

PC12 cell neuronal differentiation is associated with prolonged p21ras activity and consequent prolonged ERK activity

Expression of oncogenic ras in PC12 cells causes neuronal differentiation and sustained protein tyrosine phosphorylation and activity of extracellular signal-regulated kinases (ERKs), p42erk2 and p44erk1. Oncogenic N-ras-induced neuronal differentiation is inhibited by compounds that block ERK protein tyrosine phosphorylation or ERK activity, indicating that ERKs are not only activated by p21ras but serve as the primary downstream effectors of p21ras. Treatment of PC12 cells with nerve growth factor or fibroblast growth factor results in neuronal differentiation and in a sustained elevation of p21ras activity, of ERK activity, and of ERK tyrosine phosphorylation. Epidermal growth factor, which does not cause neuronal differentiation, stimulates only transient (< 1 hr) activation of p21ras and ERKs. These data indicate that transient activation of p21ras and, consequently, ERKs is not sufficient for induction of neuronal differentiation. Prolonged ERK activity is required: a consequence of sustained activation of p21ras by the growth factor receptor protein tyrosine kinase.

Involvement of MAP kinase activators in angiotensin II-induced activation of MAP kinases in cultured vascular smooth muscle cells

In cultured vascular smooth muscle cells (VSMC) angiotensin II (ang II) induces tyrosine and serine/threonine phosphorylation and activation of two mitogen-activated protein (MAP) kinases. When extracts of ang II-stimulated VSMC were fractionated by Mono Q anion-exchange column chromatography, three peaks of the activities which in vitro activate inactive MAP kinases were detected. These MAP kinase activator activities were not detected in extracts of unstimulated VSMC. In vitro activation of MAP kinases by the MAP kinase activators was accompanied by tyrosine and serine/threonine phosphorylation of MAP kinases. These results suggest that the MAP kinase activators are involved in the ang II-induced phosphorylation and activation of MAP kinases in VSMC.

Activation of mitogen-activated protein kinase kinase by v-Raf in NIH 3T3 cells and in vitro

Mitogen-activated protein (MAP) kinases are 42- and 44-kD serine-threonine protein kinases that are activated by tyrosine and threonine phosphorylation in cells stimulated with mitogens and growth factors. MAP kinase and the protein kinase that activates it (MAP kinase kinase) were constitutively activated in NIH 3T3 cells infected with viruses containing either of two oncogenic forms (p35EC12, p3722W) of the c-Raf-1 protein kinase. The v-Raf proteins purified from cells infected with EC12 or 22W viruses activated MAP kinase kinase from skeletal muscle in vitro. Furthermore, a bacterially expressed v-Raf fusion protein (glutathione S-transferase-p3722W) also activated MAP kinase kinase in vitro. These findings suggest that one function of c-Raf-1 in mitogenic signaling is to phosphorylate and activate MAP kinase kinase.

Angiotensin II stimulates two myelin basic protein/microtubule-associated protein 2 kinases in cultured vascular smooth muscle cells

In cultured vascular smooth muscle cells, angiotensin II (Ang II) stimulated a cytosolic protein kinase activity toward myelin basic protein (MBP) in a time- and dose-dependent manner. Phorbol 12-myristate 13-acetate (PMA) and phorbol 12,13-dibutyrate also increased the MBP kinase activity. Downregulation of protein kinase C by prolonged treatment of the cells with phorbol 12,13-dibutyrate markedly attenuated the Ang II- and PMA-induced MBP kinase activation. The Ang II- and PMA-stimulated MBP kinase activities were resolved almost equally into two distinct fractions on Mono-Q HR5/5 column chromatography (kinase 1 and kinase 2). The kinase assay in polyacrylamide gel revealed that apparent molecular masses of kinase 1 and kinase 2 were 40 and 45 kd, respectively. Microtubule-associated protein 2 also served as a substrate for both the kinases. Immunoblot analysis with an antiphosphotyrosine antibody suggested that both the kinases were tyrosine-phosphorylated during the action of Ang II. Phosphoamino acid analysis revealed that Ang II and PMA induced phosphorylation of both the kinases on serine/threonine as well as tyrosine residues. Phosphopeptide mapping patterns of kinase 1 and kinase 2 isolated from Ang II-stimulated cells were almost identical with those from PMA-stimulated cells. These results indicate that in vascular smooth muscle cells Ang II activates two species of MBP/microtubule-associated protein 2 kinases mainly through the protein kinase C-signaling pathway and suggest that tyrosine and serine/threonine phosphorylation may be involved in this process.

Raf-1 activates MAP kinase-kinase

The normal cellular homologue of the acutely transforming oncogene v-raf is c-raf-1, which encodes a serine/threonine protein kinase that is activated by many extracellular stimuli. The physiological substrates of the protein c-Raf-1 are unknown. The mitogen-activated protein (MAP) kinases Erk1 and 2 are also activated by mitogens through phosphorylation of Erk tyrosine and threonine residues catalysed by a protein kinase of relative molecular mass 50,000, MAP kinase-kinase (MAPK-K). Here we report that MAPK-K as well as Erk1 and 2 are constitutively active in v-raf-transformed cells. MAPK-K partially purified from v-raf-transformed cells or from mitogen-treated cells can be deactivated by phosphatase 2A. c-Raf-1 purified after mitogen stimulation can reactivate the phosphatase 2A-inactivated MAPK-K over 30-fold in vitro. c-Raf-1 reactivation of MAPK-K coincides with the selective phosphorylation at serine/threonine residues of a polypeptide with M(r) 50,000 which coelutes precisely on cation-exchange chromatography with the MAPK-K activatable by c-Raf-1. These results indicate that c-Raf-1 is an immediate upstream activator of MAPK-K in vivo. To our knowledge, MAPK-K is the first physiological substrate of the c-raf-1 protooncogene product to be identified.