Fluctuations of cellular, available zinc modulate insulin signaling via inhibition of protein tyrosine phosphatases.

Extracellular zinc ions are effectors of many signaling pathways in mammalian cells, including the insulin/IGF-1 pathway. Molecular targets of zinc are intracellular, however, because otherwise ineffective zinc concentrations alter the extent of protein phosphorylation only in the presence of the ionophore pyrithione. The tight inhibition of protein tyrosine phosphatases by zinc (nanomolar inhibition constants) is likely responsible for the known insulinomimetic effects of zinc ions, which increase net phosphorylation of the insulin/IGF-1-receptors and activate their signaling cascades. More importantly, not only do extracellular zinc ions affect signal transduction, but growth factors induce cellular zinc fluctuations that are of sufficient magnitude to inhibit protein tyrosine phosphatases. In conclusion, a pool of cellular, available zinc participates in phosphorylation/dephosphorylation cascades, suggesting the existence of a cellular signaling system based on zinc as a second messenger.     

The specificity of extracellular signal-regulated kinase 2 dephosphorylation by protein phosphatases

The extracellular signal-regulated protein kinase 2 (ERK2) is the founding member of a family of mitogen-activated protein kinases (MAPKs) that are central components of signal transduction pathways for cell proliferation, stress responses, and differentiation. The MAPKs are unique among the Ser/Thr protein kinases in that they require both Thr and Tyr phosphorylation for full activation. The dual phosphorylation of Thr-183 and Tyr-185 in ERK2 is catalyzed by MAPK/ERK kinase 1 (MEK1). However, the identity and relative activity of protein phosphatases that inactivate ERK2 are less well established. In this study, we performed a kinetic analysis of ERK2 dephosphorylation by protein phosphatases using a continuous spectrophotometric enzyme-coupled assay that measures the inorganic phosphate produced in the reaction. Eleven different protein phosphatases, many previously suggested to be involved in ERK2 regulation, were compared, including tyrosine-specific phosphatases (PTP1B, CD45, and HePTP), dual specificity MAPK phosphatases (VHR, MKP3, and MKP5), and Ser/Thr protein phosphatases (PP1, PP2A, PP2B, PP2C alpha, and lambda PP). The results provide biochemical evidence that protein phosphatases display exquisite specificity in their substrate recognition and implicate HePTP, MKP3, and PP2A as ERK2 phosphatases. The fact that ERK2 inactivation could be carried out by multiple specific phosphatases shows that signals can be integrated into the pathway at the phosphatase level to determine the cellular response to external stimuli. Important insights into the roles of various protein phosphatases in ERK2 kinase signaling are obtained, and further analysis of the mechanism by which different protein phosphatases recognize and inactivate MAPKs will increase our understanding of how this kinase family is regulated.     

Regulation of casein kinase 2 by phosphorylation/dephosphorylation.

The effects of various polycation-stimulated (PCS) phosphatases and of the active catalytic subunit of the ATPMg-dependent (AMDc) protein phosphatase on the activity of casein kinase 2 (CK-2) were investigated by using the synthetic peptide substrate Ser-Glu-Glu-Glu-Glu-Glu, whose phosphorylated derivative is entirely insensitive to these protein phosphatases. Previous dephosphorylation of native CK-2 enhances its specific activity 2-3-fold. Such an effect, accounted for by an increase in Vmax, is more readily promoted by the PCS phosphatases than by the AMDc phosphatase. The phosphate incorporated by autophosphorylation could not be removed by the protein phosphatases, suggesting the involvement of phosphorylation site(s) other than the one(s) affected by intramolecular autophosphorylation. The activation of CK-2 by the phosphatase pretreatment is neutralized during the kinase assay; the mechanism of this phenomenon, which is highly dependent on the kinase concentration, is discussed.     

Protein phosphatases and their regulation in the control of mitosis

Cell cycle transitions depend on protein phosphorylation and dephosphorylation. The discovery of cyclin-dependent kinases (CDKs) and their mode of activation by their cyclin partners explained many important aspects of cell cycle control. As the cell cycle is basically a series of recurrences of a defined set of events, protein phosphatases must obviously be as important as kinases. However, our knowledge about phosphatases lags well behind that of kinases. We still do not know which phosphatase(s) is/are truly responsible for dephosphorylating CDK substrates, and we know very little about whether and how protein phosphatases are regulated. Here, we summarize our present understanding of the phosphatases that are important in the control of the cell cycle and pose the questions that need to be answered as regards the regulation of protein phosphatases.     

Peptide microarrays for high-throughput studies of Ser/Thr phosphatases

Protein phosphorylation and dephosphorylation play an important role in regulation of intracellular signal transduction pathways in the biological system. A key step in the biological characterization of phosphatases and their use as drug targets is the identification of their cellular partners and suitable substrates for potential inhibitor development. Herein we describe a microarray-based protocol to map the substrate specificity of protein Ser/Thr phosphatases. This protocol uses Pro-Q dye to sensitively and quantitatively detect the amount of dephosphorylation that occurs from many putative peptide substrates in parallel, and therefore could be used to generate the so-called peptide substrate fingerprints as well as detailed kinetic information of a target phosphatase. Excluding the synthesis of the peptide substrates, the whole protocol takes a total of 11 h to complete and in future can be readily extended to the study of other classes of phosphatases, i.e., protein tyrosine phosphatases.     

The protein phosphatases involved in cellular regulation. 1. Modulation of protein phosphatases-1 and 2A by histone H1, protamine, polylysine and heparin

The phosphorylase phosphatases in rat and rabbit liver cytosol that are markedly stimulated by histone H1, protamine and polylysine were identified as protein phosphatases-2A0, 2A1 and 2A2 by anion-exchange chromatography, gel-filtration and immunotitration experiments. Histone H1 and protamine also stimulated the dephosphorylation of phosphorylase kinase, glycogen synthase, fructose-1,6-bisphosphatase, pyruvate kinase, acetyl-CoA carboxylase and phenylalanine hydroxylase by phosphatases-2A1 and 2A2, and with several of these substrates activation was even more striking (20-100-fold) than that observed with phosphorylase (approximately 5-fold). Activation by basic polypeptides did not involve dissociation of these phosphatases to the free catalytic subunit. The dephosphorylation of phosphorylase by protein phosphatase-1 was suppressed by basic polypeptides, protamine and polylysine being the most potent inhibitors. However, the dephosphorylation of glycogen synthase, pyruvate kinase and acetyl-CoA carboxylase were markedly stimulated by histone H1 and protamine (2-13-fold). Consequently, with the appropriate substrates, protein phosphatase-1 can also be regarded as a basic-polypeptide-activated protein phosphatase. Heparin stimulated (1.5-2-fold) the dephosphorylation of phosphorylase by phosphatases-2A0 and 2A1, provided that Mn2+ was present, but phosphatase-2A2 and the free catalytic subunit of phosphatase-2A were unaffected. Heparin, in conjunction with Mn2+, also stimulated (1.5-fold) the dephosphorylation of glycogen synthase (labelled in sites 3 abc), phosphorylase kinase and phenylalanine hydroxylase by phosphatase-2A1, but not by phosphatase-2A2. By contrast, the dephosphorylation of phosphorylase and phosphorylase kinase by protein phosphatase-1 was inhibited by heparin. However, dephosphorylation of glycogen synthase and pyruvate kinase by phosphatase-1 was stimulated by this mucopolysaccharide. The studies demonstrate that basic proteins can be used to distinguish protein phosphatase-1 from protein phosphatase-2A, but only if phosphorylase is employed as substrate. Optimal differentiation of the two phosphatases is observed at 30 micrograms/ml protamine or at heparin concentrations greater than 150 microM.     

Assay of protein tyrosine phosphatases by using matrix-assisted laser desorption ionization time-of-flight mass spectrometry

A nonradioactive assay for protein tyrosine phosphatases (PTPs), employing a tyrosine-phosphorylated peptide as a substrate, has been developed and applied to analyze purified enzymes, cell extracts, and immunoprecipitates. The reaction was followed by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) in a linear and positive ion mode with delayed extraction. MALDI-TOF MS detects a loss of peptide mass by 80 Da as a result of dephosphorylation and, more importantly, it yields phospho-peptide to dephosphorylated product peak intensity ratios proportional to their concentration ratios. A strong bias of the MALDI-TOF MS toward detection of the non-phospho-peptide allows accurate detection of small fractions of dephosphorylation. The method is highly sensitive and reproducible. It can be applied to general assays of protein phosphatases with various phospho-peptides as substrates.     

Tyrosine phosphorylation/dephosphorylation controls capping of Fcgamma receptor II in U937 cells

In the capping of cell-surface receptors two stages can be distinguished: 1) clustering of the receptors (patching) induced by cross-linking with specific antibodies and 2) subsequent assembly of patches into a cap which is driven by the actin-based cytoskeleton. We found that patching of Fcgamma receptor II in U937 cells was correlated with tyrosine phosphorylation of certain proteins, most prominently those of 130, 110, 75 and 28 kDa. The phosphotyrosine-bearing proteins were accumulated at the receptor patches. Formation of the receptor caps was coincident with dephosphorylation of these proteins. Inhibition of protein tyrosine kinases with herbimycin A and genistein attenuated the protein tyrosine hyperphosphorylation and blocked capping in a dose-dependent manner. Phenylarsine oxide and pervanadate, inhibitors of protein tyrosine phosphatases, also suppressed capping of Fcgamma receptor II in a concentration-dependent fashion. Simultaneously, tyrosine hyperphosphorylation of proteins occurred. In the presence of the tyrosine kinase and phosphatase inhibitors the receptors were arrested at the patching stage. In contrast, okadaic acid, a serine/threonine phosphatase blocker, did not affect assembly of the receptor caps. The inhibitory effect of phenylarsine oxide was rapidly reversed by dithiols, 2,3-dimercapto-1-propanoldithiol and dithiotreitol, and was coincident with dephosphorylation of protein tyrosine residues. Extensive washing of pervanadate-exposed cells also resulted in progressive restoration of the cap assembly. Using streptolysin O-permeabilized cells we confirmed regulatory function played by dephosphorylation of tyrosine residues in capping of Fcgamma receptor II. Exogenous phosphatases, applied to permeabilized cells in which activity of endogenous tyrosine phosphatases was blocked, evoked dephosphorylation of protein tyrosine residues that was accompanied by recovery of capping ability in the cells.     

Characterization of Neuronal Protein Phosphatases in Aplysia californica

Biochemical properties of neuronal protein phosphatases from Aplysia californica were characterized. Dephosphorylation of phosphorylase alpha by extracts of abdominal ganglia and clusters of sensory neurons from pleural ganglia was demonstrated. Type-1 protein phosphatase (PrP-1) was identified in these extracts by the dephosphorylation of the beta-subunit of phosphorylase kinase and its inhibition by the protein, inhibitor-2. Type-2A protein phosphatase (PrP-2A) was demonstrated by the dephosphorylation of the alpha-subunit of phosphorylase kinase, which was insensitive to inhibitor-2. As in vertebrate tissues, only four enzymes, PrP-1 (47%), PrP-2A (42%), PrP-2B (11%), and PrP-2C (less than 1%), accounted for all the cellular protein phosphatase activity dephosphorylating phosphorylase kinase. Aplysia PrP-1 and PrP-2A were potently inhibited by okadaic acid, with PrP-1 being approximately 20-fold more sensitive than PrP-2A. By comparison, purified PrP-2A from rabbit skeletal muscle was 15- to 20-fold more sensitive to okadaic acid than PrP-1 from the same source. Only PrP-1 was associated with the particulate fractions from Aplysia neurons, whereas PrP-1 and PrP-2A, -2B, and -2C were all present in the cytosol. Extraction of the particulate PrP-1 decreased its sensitivity to okadaic acid by sixfold, suggesting that cellular factor(s) affect its sensitivity to this inhibitor. In most respects, protein phosphatases from Aplysia neurons resemble their mammalian counterparts, and their biochemical characterization sets the stage for examining the role of these enzymes in neuronal plasticity, and in learning and memory.     

Enzymatic activity and substrate specificity of mitogen-activated protein kinase p38alpha in different phosphorylation states

The mitogen-activated protein (MAP) kinases are essential signaling molecules that mediate many cellular effects of growth factors, cytokines, and stress stimuli. Full activation of the MAP kinases requires dual phosphorylation of the Thr and Tyr residues in the TXY motif of the activation loop by MAP kinase kinases. Down-regulation of MAP kinase activity can be initiated by multiple serine/threonine phosphatases, tyrosine-specific phosphatases, and dual specificity phosphatases (MAP kinase phosphatases). This would inevitably lead to the formation of monophosphorylated MAP kinases. However, the biological functions of these monophosphorylated MAP kinases are currently not clear. In this study, we have prepared MAP kinase p38alpha, a member of the MAP kinase family, in all phosphorylated forms and characterized their biochemical properties. Our results indicated the following: (i) p38alpha phosphorylated at both Thr-180 and Tyr-182 was 10-20-fold more active than p38alpha phosphorylated at Thr-180 only, whereas p38alpha phosphorylated at Tyr-182 alone was inactive; (ii) the dual-specific MKP5, the tyrosine-specific hematopoietic protein-tyrosine phosphatase, and the serine/threonine-specific PP2Calpha are all highly specific for the dephosphorylation of p38alpha, and the dephosphorylation rates were significantly affected by different phosphorylated states of p38alpha; (iii) the N-terminal domain of MPK5 has no effect on enzyme catalysis, whereas deletion of the MAP kinase-binding domain in MKP5 leads to a 370-fold decrease in k(cat)/K(m) for the dephosphorylation of p38alpha. This study has thus revealed the quantitative contributions of phosphorylation of Thr, Tyr, or both to the activation of p38alpha and to the substrate specificity for various phosphatases.     

Metal dependent protein phosphatase PPM family in cardiac health and diseases

Protein phosphorylation and dephosphorylation is central to signal transduction in nearly every aspect of cellular function, including cardiovascular regulation and diseases. While protein kinases are often regarded as the molecular drivers in cellular signaling with high specificity and tight regulation, dephosphorylation mediated by protein phosphatases is also gaining increasing appreciation as an important part of the signal transduction network essential for the robustness, specificity and homeostasis of cell signaling. Metal dependent protein phosphatases (PPM, also known as protein phosphatases type 2C, PP2C) belong to a highly conserved family of protein phosphatases with unique biochemical and molecular features. Accumulating evidence also indicates important and specific functions of individual PPM isoform in signaling and cellular processes, including proliferation, senescence, apoptosis and metabolism. At the physiological level, abnormal PPM expression and activity have been implicated in major human diseases, including cancer, neurological and cardiovascular disorders. Finally, inhibitors for some of the PPM members have been developed as a potential therapeutic strategy for human diseases. In this review, we will focus on the background information about the biochemical and molecular features of major PPM family members, with emphasis on their demonstrated or potential roles in cardiac pathophysiology. The current challenge and potential directions for future investigations will also be highlighted.     

Interaction of plasma lipoproteins with erythrocytes. II. Modulation of membrane-associated enzymes.

When incubated with intact erythrocytes, low density lipoproteins (LDL) decrease the phosphate content of erythrocyte spectrin allowing the cells to undergo morphological transformation. The phosphate content of spectrin depends on the balance between the activity of membrane-associated cyclic AMP-independent protein kinases and phosphoprotein phosphates. LDL do not influence the activity of membrane-associated cyclic AMP-independent protein kinases; these lipoproteins activate by 2-fold and greater membrane-associated phosphatases as determined by hydrolysis of p-nitrophenyl phosphate and by phosphate hydrolysis of phosphorylated erythrocyte membrane proteins. We conclude that LDL interact at the exterior surface of the erythrocyte to stimulate dephosphorylation of spectrin. The significance of this conclusion is augmented by the fact that spectrin, the target for LDL-induced dephosphorylation, specifies cell morphology and modulates the distribution of cell-surface receptors. LDL also render erythrocyte acetylcholinesterase less susceptible to inhition by F-. Lipoproteins in the high density class (HDL) do not stimulate dephosphorylation of spectrin, and they are consequently unable to alter erythrocyte morphology. HDL do prevent the LDL-induced activation of membrane phosphatase. The inhibitory capacity of HDL is observed over the range of LDL:HDL (w/w) which exists in the plasma of normolipemic humans.     

Molecular basis for substrate specificity of protein kinases and phosphatases

Regulation of various metabolic processes occurs by the phosphorylation/dephosphorylation of enzymes. Both the protein kinases that catalyze the phosphorylations and the protein phosphatases that catalyze the dephosphorylations display relatively broad specificity, reacting with a number of distinct sites in target enzymes. In this way changes in the activity of a particular kinase or phosphatase can cause coordinated and pleiotropic responses. However, the kinases and phosphatases do not exhibit a one-to-one correspondence in their reactions. Residues at different positions may be phosphorylated by a single kinase, yet dephosphorylated by different individual phosphatases. Conversely, sites which are substrates for different individual kinases may be dephosphorylated by a single phosphatase. In exploring the molecular basis for these differences this article shows that whereas kinases react with specific primary structures that often times appear as beta bends, the phosphatases recognize higher order structure, less strictly ruled by amino acid sequence surrounding the phosphorylated site. The differences, seen in the ability of these enzymes to utilize synthetic peptide substrates, might be rationalized in terms of function. Kinases need protruding segments of structure that can be enwrapped to exclude water, thereby minimizing ATP hydrolysis and enhancing phosphotransferase activity. On the other hand phosphatases are hydrolytic enzymes that may operate especially well on protein interfaces. Hydrolytic action often measured with p-nitrophenylphosphate is not necessarily indicative of a protein phosphatase and consideration of the mechanism reveals why this substrate can be misleading.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nitric oxide and superoxide inhibit platelet-derived growth factor receptor phosphotyrosine phosphatases

Platelet derived growth factor receptor (PDGFR) became tyrosine autophosphorylated in rat mesangial cells shortly after platelet derived growth factor (PDGF) ligation in a tyrosine kinase inhibitor (tyrphostin AG 1296) sensitive manner. Ligand-independent, massive tyrosine PDGFR phosphorylation was achieved by diverse NO releasing compounds. Phosphorylation was slow compared to PDGF, revealed a concentration- and time-dependency, and was not mimicked by lipophilic cyclic-GMP analogues. Interleukin-1 beta/cAMP activated mesangial cells released NO and in turn showed PDGFR phosphorylation. A NO-synthase involvement was assured by L-NG-nitroarginine methyl ester inhibition. PDGFR phosphorylation was also achieved by the redox cycler 2,3-dimethoxy-1,4-naphthoquinone. NO- and O2(.-)-evoked PGDFR phosphorylation was N-acetylcysteine reversible. Cell free dephosphorylation assays revealed PDGFR dephosphorylation by tyrosine phosphatases. Receptor dephosphorylation by cytosolic phosphatases was completed within 30 min and was sensitive to the readdition of NO donors or orthovanadate. In addition, phosphatase activity determined in a direct dephosphorylation assay using the substrate para-nitrophenyl phosphate was attenuated by NO or vanadate. We conclude that cytosolic protein tyrosine phosphatases are targeted by exogenously supplied or endogenously generated NO in mesangial cells. Radical (NO. or O2.-) formation shifts the phosphorylation--dephosphorylation equilibrium towards phosphorylation, thus integrating redox-mediated responses into established signal transducing pathways.     

Phosphotyrosine Substrate Sequence Motifs for Dual Specificity Phosphatases

Protein tyrosine phosphatases dephosphorylate tyrosine residues of proteins, whereas, dual specificity phosphatases (DUSPs) are a subgroup of protein tyrosine phosphatases that dephosphorylate not only Tyr(P) residue, but also the Ser(P) and Thr(P) residues of proteins. The DUSPs are linked to the regulation of many cellular functions and signaling pathways. Though many cellular targets of DUSPs are known, the relationship between catalytic activity and substrate specificity is poorly defined. We investigated the interactions of peptide substrates with select DUSPs of four types: MAP kinases (DUSP1 and DUSP7), atypical (DUSP3, DUSP14, DUSP22 and DUSP27), viral (variola VH1), and Cdc25 (A-C). Phosphatase recognition sites were experimentally determined by measuring dephosphorylation of 6,218 microarrayed Tyr(P) peptides representing confirmed and theoretical phosphorylation motifs from the cellular proteome. A broad continuum of dephosphorylation was observed across the microarrayed peptide substrates for all phosphatases, suggesting a complex relationship between substrate sequence recognition and optimal activity. Further analysis of peptide dephosphorylation by hierarchical clustering indicated that DUSPs could be organized by substrate sequence motifs, and peptide-specificities by phylogenetic relationships among the catalytic domains. The most highly dephosphorylated peptides represented proteins from 29 cell-signaling pathways, greatly expanding the list of potential targets of DUSPs. These newly identified DUSP substrates will be important for examining structure-activity relationships with physiologically relevant targets.     

Characterization of the major phosphofructokinase-dephosphorylating protein phosphatases from Ascaris suum muscle.

In contrast to the mammalian enzyme, PFK from the nematode Ascaris suum is activated following phosphorylation (Daum et al. (1986) Biochem. Biophys. Res. Commun. 139, 215-221) catalyzed by a cAMP-dependent protein kinase (Thalhofer et al. (1988) J. Biol. Chem. 263, 952-957). In the present report, we describe the characterization of the major PFK dephosphorylating phosphatases from Ascaris muscle. Two of these phosphatases exhibit apparent M(r) values of 174,000 and 126,000, respectively, and are dissociated to active 33 kDa proteins by ethanol precipitation. Denaturing electrophoresis of each of the enzyme preparations showed two bands of M(r) 33,000 and 63,000. The enzymes are classified as type 2A phosphatases according to their inhibition by subnanomolar concentrations of okadaic acid, the lack of inhibition by heat-stable phosphatase inhibitors 1 and 2, and their preference for the alpha- rather than for the beta-subunit of phosphorylase kinase. Like other type 2A phosphatases, they exhibit broad substrate specificities, are activated by divalent cations and polycations, and inhibited by fluoride, inorganic phosphate and adenine nucleotides. In addition, we have found that PFK is also dephosphorylated by an unusual protein phosphatase. This exhibits kinetic properties similar to type 2A protein phosphatases, but has a distinctly lower sensitivity towards inhibition by okadaic acid (IC50 approx. 20 nM). Partial purification of the enzyme provided evidence that it is composed of a 30 kDa catalytic subunit and probably two other subunits (molecular masses 66 and 72 kDa). The dephosphorylation of PFK by protein phosphatases is strongly inhibited by heparin. This effect, however, is substrate-specific and does not occur with Ascaris phosphorylase a.     

Dephosphorylation and inactivation of phosphorylase kinase: subunit specificity of rabbit skeletal muscle protein phosphatases

The dephosphorylation of phosphorylase kinase by four rabbit skeletal muscle protein phosphatases was studied. The four enzymes used were preparations of protein phosphatases C-I, C-II, H-I, and H-II. Phosphatases C-I, C-II, and H-II were obtained as homogeneous preparations using procedures previously developed. Phosphatase H-I was purified 644-fold from rabbit skeletal muscle for the purposes of this study, and was the major phosphorylase phosphatase activity in the tissue extract. Phosphatases C-I and H-I were relatively specific for removal of the beta subunit phosphate of phosphorylase kinase, this occurring at rates approximately 100 times more rapidly than the removal of the alpha subunit phosphate. In contrast, phosphatases C-II and H-II readily dephosphorylated both the alpha and beta subunits, although the alpha subunit phosphate release occurred at rates about twice that of the beta subunit phosphate. These studies show that skeletal muscle contains two phosphatases capable of acting on phosphorylase kinase, and that these have different specificities as represented by phosphatases H-I and C-I on the one hand, and phosphatases C-II and H-II on the other hand. These studies also provided unequivocal evidence that dephosphorylation of the beta subunit of phosphorylase kinase is solely involved in the inactivation of the cAMP-dependent protein kinase-activated enzyme. When autophosphorylated phosphorylase kinase was used as the substrate, the four phosphatases displayed similar general specificities as they did toward the cAMP-dependent protein kinase-activated enzyme. With none of the phosphatases examined was there any evidence that alpha subunit phosphorylation affected the rate of beta subunit dephosphorylation.     

Tyrosine Hydroxylase Dephosphorylation by Protein Phosphatase 2A in Bovine Adrenal Chromaffin Cells

This study was undertaken to characterise the protein phosphatases in bovine adrenal chromaffin cells acting on tyrosine hydroxylase. Cells were pre-labelled with ³²P_i and permeabilized with digitonin. The extent of dephosphorylation of Ser-8, Ser-19, Ser-31 and Ser-40 on tyrosine hydroxylase was found to be 30%, 38%, 37% and 71% respectively over 5 min. For Ser-19, Ser-31 and Ser-40 the dephosphorylation was entirely due to protein phosphatase 2A, as the dephosphorylation could be completely blocked by microcystin, but not by the protein phosphatase 1 inhibitory peptide. Permeabilization did not change the distribution of protein phosphatase 2A or tyrosine hydroxylase, or the activity of PP2A, from that occurring in intact cells. The dephosphorylation of Ser-8 was not altered by any inhibitor, suggesting the involvement of other protein phosphatases. The method developed here can be used to determine the protein phosphatases acting on substrates in conditions closely approximating those in situ, including the endogenous state of substrate phosphorylation and phosphatase location.     

Mos activates MAP kinase in mouse oocytes through two opposite pathways

Activation of mitogen-activated protein kinase (MAPK) in maturing mouse oocytes occurs after synthesis of Mos, a MAPKKK. To investigate whether Mos acts only through MEK1, we microinjected constitutively active forms of MEK1 (MEK1S218D/S222D referred herein as MEK*) and Raf (DeltaRaf) into mouse oocytes. In mos(-/-) oocytes, which do not activate MAPK during meiosis and do not arrest in metaphase II, MEK* and DeltaRaf did not rescue MAPK activation and metaphase II arrest, whereas Mos induced a complete rescue. MEK* and DeltaRaf induced cleavage arrest of two-cell blastomeres. They induced MAPK activation when protein phosphatases were inhibited by okadaic acid, suggesting that Mos may inhibit protein phosphatases. Finally, in mos(-/-) oocytes, MEK* induced the phosphorylation of Xp42(mapk)D324N, a mutant less sensitive to dephosphorylation, showing that a MAPK phosphatase activity is present in mouse oocytes. We demonstrate that active MAPKK or MAPKKK cannot substitute for Mos to activate MAPK in mouse oocytes. We also show that a phosphatase activity inactivates MAPK, and that Mos can overcome this inhibitory activity. Thus Mos activates MAPK through two opposite pathways: activation of MEK1 and inhibition of a phosphatase.