Glucose and type 2A protein phosphatase regulate the interaction between catalytic and regulatory subunits of AMP-activated protein kinase

We have expressed in yeast the different subunits of AMP-activated protein kinase (AMPK) and, by using the two-hybrid system, we have found a glucose-regulated interaction between alpha 2 catalytic and gamma 1 regulatory subunits. This regulation was not affected by known regulators of the corresponding yeast orthologue, the SNF1 complex, such as Reg1 or Hxk2, but it was affected by deletion of regulatory subunits of yeast type 2A protein phosphatase (PP2A) complex. We have also found that Tpd3 and PR65 alpha, the corresponding yeast and mammalian A subunits of PP2A, interacted with AMPK alpha 2 both in yeast and mammals, respectively. This interaction occurred only through the regulatory domain of this subunit. These results suggested a direct involvement of PP2A complex in regulating the interaction between AMPK alpha 2 and gamma 1 in a glucose-dependent manner.     

Effects of regulatory subunits on the kinetics of protein phosphatase 2A

Both the scaffold (A) and the regulatory (R) subunits of protein phosphatase 2A regulate enzyme activity and specificity. Heterotrimeric enzymes containing different R-subunits differ in their specific activities for substrates. Kinetic parameters for the dephosphorylation of a phosphopeptide by different oligomeric forms of PP2A were determined to begin to elucidate the molecular basis of regulatory subunit effects on phosphatase activity. Using steady state kinetics and the pH dependence of kinetic parameters, we have explored the effect of the A- and R-subunits on the kinetic and chemical mechanism of PP2A. The regulatory subunits affected a broad range of kinetic parameters. The C-subunit and AC dimer were qualitatively similar with respect to the product inhibition patterns and the pH dependence of kinetic parameters. However, a 22-fold decrease in rate and a 4.7-fold decrease in K(m) can be attributed to the presence of the A-subunit. The presence of the R2alpha (Balpha or PR55alpha) subunit caused an additional decrease in K(m) and changed the kinetic mechanism of peptide dephosphorylation. The R2alpha-subunit also caused significant changes in the pH dependence of kinetic parameters as compared to the free C subunit or AC heterodimer. The data support an important role for the regulatory subunits in determining both the affinity of PP2A heterotrimers for peptide substrates and the mechanism by which they are dephosphorylated.     

Structural basis for the recognition of regulatory subunits by the catalytic subunit of protein phosphatase 1.

The diverse forms of protein phosphatase 1 in vivo result from the association of its catalytic subunit (PP1c) with different regulatory subunits, one of which is the G-subunit (G(M)) that targets PP1c to glycogen particles in muscle. Here we report the structure, at 3.0 A resolution, of PP1c in complex with a 13 residue peptide (G(M[63-75])) of G(M). The residues in G(M[63-75]) that interact with PP1c are those in the Arg/Lys-Val/Ile-Xaa-Phe motif that is present in almost every other identified mammalian PP1-binding subunit. Disrupting this motif in the G(M[63-75]) peptide and the M(110[1-38]) peptide (which mimics the myofibrillar targeting M110 subunit in stimulating the dephosphorylation of myosin) prevents these peptides from interacting with PP1. A short peptide from the PP1-binding protein p53BP2 that contains the RVXF motif also interacts with PP1c. These findings identify a recognition site on PP1c, invariant from yeast to humans, for a critical structural motif on regulatory subunits. This explains why the binding of PP1 to its regulatory subunits is mutually exclusive, and suggests a novel approach for identifying the functions of PP1-binding proteins whose roles are unknown.     

Expression of the A subunit of protein phosphatase 2A and characterization of its interactions with the catalytic and regulatory subunits.

The alpha form of the A subunit of human protein phosphatase 2A was expressed in insect cells following infection with a recombinant baculovirus. A alpha was expressed as a soluble protein that comprised approximately 10% of total cellular protein. The expressed A alpha subunit was purified by chromatography on amino-hexyl-Sepharose and Mono Q with a yield of 2 mg/500-ml culture. The recombinant protein had the same apparent molecular mass as the bovine cardiac protein and was devoid of myosin light chain phosphatase activity. Biological activity of expressed A was assessed by assays of complex formation with the catalytic (C) and B subunits, purified from bovine cardiac tissue, and by inhibition of phosphatase activity. Purified A alpha had a high apparent affinity for C (IC50 = 0.10 nM) and bound with a stoichiometry of 1 mol of A/mol of C. Interaction of A alpha with the catalytic subunit caused a maximal inhibition of myosin light chain and phosphorylase phosphatase activities of 50 and 79%, respectively. The AC complex prepared by reconstitution of recombinant A alpha with C had the same electrophoretic mobility in nondenaturing polyacrylamide gels and the same elution volume when chromatographed on a size exclusion column as the native AC complex purified from cardiac muscle. Similar chromatographic profiles were also observed for the heterotrimer reconstituted from recombinant A alpha, purified B and C, and the native bovine cardiac heterotrimeric holoenzyme. Cross-linking of the native enzyme and the reconstituted heterotrimer generated the same pattern of high molecular weight species. Immunological analyses of these complexes demonstrated that distinct cross-linked forms composed of ABC, AC, AB, and BC were obtained. These results suggest that each of the three subunits of protein phosphatase 2A forms direct contacts with both of the others.     

Protein phosphatase 2A regulatory subunits and cancer

The serine/threonine protein phosphatase (PP2A) is a trimeric holoenzyme that plays an integral role in the regulation of a number of major signaling pathways whose deregulation can contribute to cancer. The specificity and activity of PP2A are highly regulated through the interaction of a family of regulatory B subunits with the substrates. Accumulating evidence indicates that PP2A acts as a tumor suppressor. In this review we summarize the known effects of specific PP2A holoenzymes and their roles in cancer relevant pathways. In particular we highlight PP2A function in the regulation of MAPK and Wnt signaling.     

蛋白磷酸酶2A的亚基功能

蛋白磷酸酶2A(protein phosphatase 2A,PP2A)是一种由催化亚基C、结构亚基A和多种功能特异的调节亚基B组成的全酶复合物,其在基因表达、细胞增殖分化和信号转导等方面有重要调控作用.各种不同亚基组成功能各异的PP2A全酶,调控不同的细胞功能.各亚基在PP2A功能调控中均起关键作用.本文重点介绍PP2A各个亚基在PP2A生物学功能实现中的作用.     

The catalytic subunits of protein phosphatase-1 and protein phosphatase 2A are distinct gene products

Three forms of protein phosphatase-1 were isolated from rabbit skeletal muscle that had Mr values of 37 000, 34 000 and 33 000 determined by sodium dodecyl sulphate (SDS) gel electrophoresis. Each species dephosphorylated the beta-subunit of phosphorylase kinase very much faster than the alpha-subunit, was inhibited by inhibitors 1 and 2 with equal potency, and was converted to a form dependent on glycogen synthase kinase-3 and Mg-ATP for activity by incubation with inhibitor-2. Digestion with cyanogen bromide or Staphylococcus aureus proteinase followed by SDS gel electrophoresis showed a very similar pattern of cleavage products for all three forms. The Mr-37 000 and Mr-34 000 species were converted to the Mr-33 000 form by incubation with chymotrypsin. It is concluded that the Mr-33 000 and Mr-34 000 forms are derived from the Mr-37 000 component by limited proteolysis. Conversion of the Mr-37 000 to the Mr-33 000 form was accompanied by a two-fold increase in activity, indicating that an Mr-4000 fragment at one end of the polypeptide is an inhibitory domain that decreases enzyme activity. The catalytic subunit of protein phosphatase 2A from rabbit skeletal muscle had an Mr of 36 000 determined by SDS gel electrophoresis and its specific activity (3 kU/mg) was much lower than that of the Mr-37 000 (15-20 kU/mg) or Mr-33/34 000 (40-50 kU/mg) forms of protein phosphatase-1. It dephosphorylated the alpha-subunit of phosphorylase kinase 4-5-fold faster than the beta-subunit, was unaffected by inhibitor-1 or inhibitor-2, and preincubation with the latter protein did not result in the production of a glycogen synthase kinase-3 and Mg-ATP-dependent form of the enzyme. Digestion with chymotrypsin did not alter the electrophoretic mobility of protein phosphatase 2A under conditions that caused quantitative conversion of the Mr-37 000 form of protein phosphatase-1 to the Mr-33 000 species. Digestion with cyanogen bromide or S. aureus proteinase, followed by SDS gel electrophoresis, showed a quite different pattern of cleavage products to those observed with protein phosphatase 1. Antibody to protein phosphatase-2A raised in sheep did not cross-react with any of the forms of protein phosphatase-1, as judged by immunoelectrophoretic and immunotitration experiments. It is concluded that protein phosphatase-1 and protein phosphatase-2A are distinct gene products.     

O-GlcNAc transferase is in a functional complex with protein phosphatase 1 catalytic subunits

A hallmark of signal transduction is the dynamic and inducible post-translational modification of proteins. In addition to the well characterized phosphorylation of proteins, other modifications have been shown to be regulatory, including O-linked beta-N-acetylglucosamine (O-GlcNAc). O-GlcNAc modifies serine and threonine residues on a myriad of nuclear and cytosolic proteins, and for several proteins there appears to be a reciprocal relationship between phosphorylation and O-GlcNAc modification. Here we report further evidence of this yin-yang relationship by demonstrating that O-GlcNAc transferase, the enzyme that adds O-GlcNAc to proteins, exists in stable and active complexes with the serine/threonine phosphatases PP1beta and PP1gamma, enzymes that remove phosphate from proteins. The existence of this complex highlights the importance of understanding the dynamic relationship between O-GlcNAc and phosphate in modulating protein function in many cellular processes and disease states such as Alzheimer's disease and type II diabetes.     

V‐ATPase deactivation in blowfly salivary glands is mediated by protein phosphatase 2C

The activity of vacuolar H⁺‐ATPase (V‐ATPase) in the apical membrane of blowfly (Calliphora vicina) salivary glands is regulated by the neurohormone serotonin (5‐HT). 5‐HT induces, via protein kinase A, the phosphorylation of V‐ATPase subunit C and the assembly of V‐ATPase holoenzymes. The protein phosphatase responsible for the dephosphorylation of subunit C and V‐ATPase inactivation is not as yet known. We show here that inhibitors of protein phosphatases PP1 and PP2A (tautomycin, ocadaic acid) and PP2B (cyclosporin A, FK‐506) do not prevent V‐ATPase deactivation and dephosphorylation of subunit C. A decrease in the intracellular Mg²⁺ level caused by loading secretory cells with EDTA‐AM leads to the activation of proton pumping in the absence of 5‐HT, prolongs the 5‐HT‐induced response in proton pumping, and inhibits the dephosphorylation of subunit C. Thus, the deactivation of V‐ATPase is most probably mediated by a protein phosphatase that is insensitive to okadaic acid and that requires Mg²⁺, namely, a member of the PP2C protein family. By molecular biological techniques, we demonstrate the expression of at least two PP2C protein family members in blowfly salivary glands. © 2009 Wiley Periodicals, Inc.     

Carboxyl methylation of the phosphoprotein phosphatase 2A catalytic subunit promotes its functional association with regulatory subunits in vivo

The phosphoprotein phosphatase 2A (PP2A) catalytic subunit contains a methyl ester on its C-terminus, which in mammalian cells is added by a specific carboxyl methyltransferase and removed by a specific carboxyl methylesterase. We have identified genes in yeast that show significant homology to human carboxyl methyltransferase and methylesterase. Extracts of wild-type yeast cells contain carboxyl methyltransferase activity, while extracts of strains deleted for one of the methyltransferase genes, PPM1, lack all activity. Mutation of PPM1 partially disrupts the PP2A holoenzyme in vivo and ppm1 mutations exhibit synthetic lethality with mutations in genes encoding the B or B' regulatory subunit. Inactivation of PPM1 or overexpression of PPE1, the yeast gene homologous to bovine methylesterase, yields phenotypes similar to those observed after inactivation of either regulatory subunit. These phenotypes can be reversed by overexpression of the B regulatory subunit. These results demonstrate that Ppm1 is the sole PP2A methyltransferase in yeast and that its activity is required for the integrity of the PP2A holoenzyme.     

Prostaglandin E2/parathyroid hormone-induced suppression of alkaline phosphatase activity is mediated by protein kinase C

• 1.1. Bone resorptive factors, prostaglandin E2 and parathyroid hormone are shown to suppress alkaline phosphatase activity in a rat osteoblastic cell line.
• 2.2. Phorbol myristate acetate, but not dibutyryl cAMP or calcium ionophore can suppress alkaline phosphatase activity.
• 3.3. The protein kinase C inhibitors (H89, staurosporine) are able to block the suppression of alkaline phosphatase activity induced by prostaglandin E2 and parathyroid hormone.
• 4.4. These data suggest that protein kinase C is involved in the inhibition of alkaline phosphatase activity induced by prostaglandin E2 and parathyroid hormone.

     

Carboxyl methylation regulates phosphoprotein phosphatase 2A by controlling the association of regulatory B subunits

Phosphoprotein phosphatase 2A (PP2A) is a major phosphoserine/threonine protein phosphatase in all eukaryotes. It has been isolated as a heterotrimeric holoenzyme composed of a 65 kDa A subunit, which serves as a scaffold for the association of the 36 kDa catalytic C subunit, and a variety of B subunits that control phosphatase specificity. The C subunit is reversibly methyl esterified by specific methyltransferase and methylesterase enzymes at a completely conserved C-terminal leucine residue. Here we show that methylation plays an essential role in promoting PP2A holoenzyme assembly and that demethylation has an opposing effect. Changes in methylation indirectly regulate PP2A phosphatase activity by controlling the binding of regulatory B subunits to AC dimers.     

Two conserved domains in regulatory B subunits mediate binding to the A subunit of protein phosphatase 2A.

Protein phosphatase 2A (PP2A) is an abundant heterotrimeric serine/threonine phosphatase containing highly conserved structural (A) and catalytic (C) subunits. Its diverse functions in the cell are determined by its association with a highly variable regulatory and targeting B subunit. At least three distinct gene families encoding B subunits are known: B/B55/CDC55, B'/B56/RTS1 and B"/PR72/130. No homology has been identified among the B families, and little is known about how these B subunits interact with the PP2A A and C subunits. In vitro expression of a series of B56alpha fragments identified two distinct domains that bound independently to the A subunit. Sequence alignment of these A subunit binding domains (ASBD) identified conserved residues in B/B55 and PR72 family members. The alignment successfully predicted domains in B55 and PR72 subunits that similarly bound to the PP2A A subunit. These results suggest that these B subunits share a common core structure and mode of interaction with the PP2A holoenzyme.     

Subunit interaction sites between the regulatory and catalytic subunits of cAMP-dependent protein kinase. Identification of a specific interchain disulfide bond

The catalytic (C) subunit and the type II regulatory (RII) subunit of cAMP-dependent protein kinase can be cross-linked by interchain disulfide bonding. This disulfide bond can be catalyzed by cupric phenanthroline and also can be generated by a disulfide interchange using either RII-subunit or C-subunit that has been modified with either 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or N-4(azidophenylthio)phthalimide (APTP). When the 2 cysteine residues of the C-subunit are reacted with DTNB prior to incubation with the RII-subunit, interchain disulfide bonding occurs. Similar observations are seen with C-subunit that had been modified with APTP. Interchain disulfide bonds also form when the RII-subunit is modified with DTNB prior to incubation with the C-subunit. The presence of cAMP facilitates this cross-linking while autophosphorylation of the RII-subunit retards the rate at which the interchain disulfide bond forms. Interchain disulfide bonds also form spontaneously when the RII-subunit and the C-subunit are dialyzed at pH 8.0 in the absence of reducing agents. The specific amino acid residues that participate in intersubunit disulfide bonding have been identified as Cys-97 in the RII-subunit and Cys-199 in the C-subunit. Based on the sequence homologies of the RII-subunit with other kinase substrates and on the proximity of Cys-97 to the catalytic site, a model is proposed in which the autophosphorylation site of the RII-subunit occupies the substrate-binding site in the holoenzyme. The model also proposes that this same site may be occupied by the region flanking Cys-199 in the C-subunit when the C-subunit is dissociated.     

Cross regulation between Candida albicans catalytic and regulatory subunits of protein kinase A

In the pathogen Candida albicans protein kinase A (PKA) catalytic subunit is encoded by two genes TPK1 and TPK2 and the regulatory subunit by one gene, BCY1. PKA mediates several cellular processes such as cell cycle regulation and the yeast to hyphae transition, a key factor for C. albicans virulence. The catalytic isoforms Tpk1p and Tpk2p share redundant functions in vegetative growth and hyphal development, though they differentially regulate glycogen metabolism, the stress response pathway and pseudohyphal formation. In Saccharomyces cerevisiae it was earlier reported that BCY1 overexpression not only increased the amount of TPK3 mRNA but also its catalytic activity. In C. albicans a significant decrease in Bcy1p expression levels was already observed in tpk2Δ null strains. In this work we showed that the upregulation in Bcy1p expression was observed in a set of strains having a TPK1 or TPK2 allele reintegrated in its own locus, as well as in strains expressing the TPKs under the control of the constitutive ACT1 promoter. To confirm the cross regulation event between Bcy1p and Tpkp expression we generated a mutant strain with the lowest PKA activity carrying one TPK1 and a unique BCY1 allele with the aim to obtain two derived strains in which BCY1 or TPK1 were placed under their own promoters inserted in the RPS10 neutral locus. We found that placing one copy of BCY1 upregulated the levels of Tpk1p and its catalytic activity; while TPK1 insertion led to an increase in BCY1 mRNA, Bcy1p and in a high cAMP binding activity. Our results suggest that C. albicans cells were able to compensate for the increased levels of either Tpk1p or Tpk2p subunits with a corresponding elevation of Bcy1 protein levels and vice versa, implying a tightly regulated mechanism to balance holoenzyme formation.     

A protein phosphatase 2A catalytic subunit is a negative regulator of abscisic acid signalling

The key regulatory role of abscisic acid (ABA) in many physiological processes in plants is well established. However, compared with other plant hormones, the molecular mechanisms underlying ABA signalling are poorly characterized. In this work, a specific catalytic subunit of protein phosphatase 2A (PP2Ac-2) has been identified as a component of the signalling pathway that represses responses to ABA. A loss-of-function pp2ac-2 mutant is hypersensitive to ABA. Moreover, pp2ac-2 plants have altered responses in developmental and environmental processes that are mediated by ABA, such as primary and lateral root development, seed germination and responses to drought and high salt and sugar stresses. Conversely, transgenic plants overexpressing PP2Ac-2 are less sensitive to ABA than wild type, a phenotype that is manifested in all the above-mentioned physiological processes. DNA microarray hybridization experiments reveal that PP2Ac-2 is negatively involved in ABA responses through regulation of ABA-dependent gene expression. Moreover, the results obtained indicate that ABA antagonistically regulates PP2Ac-2 expression and PP2Ac-2 activity thus allowing plant sensitivity to the hormone to be reset after induction. Phenotypic, genetic and gene expression data strongly suggest that PP2Ac-2 is a negative regulator of the ABA pathway. Activity of protein phosphatase 2A thus emerges as a key element in the control of ABA signalling.     

The complement of protein phosphatase catalytic subunits encoded in the genome of Arabidopsis

Reversible protein phosphorylation is critically important in the modulation of a wide variety of cellular functions. Several families of protein phosphatases remove phosphate groups placed on key cellular proteins by protein kinases. The complete genomic sequence of the model plant Arabidopsis permits a comprehensive survey of the phosphatases encoded by this organism. Several errors in the sequencing project gene models were found via analysis of predicted phosphatase coding sequences. Structural sequence probes from aligned and unaligned sequence models, and all-against-all BLAST searches, were used to identify 112 phosphatase catalytic subunit sequences, distributed among the serine (Ser)/threonine (Thr) phosphatases (STs) of the protein phosphatase P (PPP) family, STs of the protein phosphatase M (PPM) family (protein phosphatases 2C [PP2Cs] subfamily), protein tyrosine (Tyr) phosphatases (PTPs), low-M(r) protein Tyr phosphatases, and dual-specificity (Tyr and Ser/Thr) phosphatases (DSPs). The Arabidopsis genome contains an abundance of PP2Cs (69) and a dearth of PTPs (one). Eight sequences were identified as new protein phosphatase candidates: five dual-specificity phosphatases and three PP2Cs. We used phylogenetic analyses to infer clustering patterns reflecting sequence similarity and evolutionary ancestry. These clusters, particularly for the largely unexplored PP2C set, will be a rich source of material for plant biologists, allowing the systematic sampling of protein function by genetic and biochemical means.