Do metabolic HAD phosphatases moonlight as protein phosphatases?

Mammalian haloacid dehalogenase (HAD)-type phosphatases have evolved to dephosphorylate a wide range of small metabolites, but can also target macromolecules such as serine/threonine, tyrosine-, and histidine-phosphorylated proteins. To accomplish these tasks, HAD phosphatases are equipped with cap domains that control access to the active site and provide substrate specificity determinants. A number of capped HAD phosphatases impact protein phosphorylation, although structural data are consistent with small metabolite substrates rather than protein substrates. This review discusses the structures, functions and disease implications of the three closely related, capped HAD phosphatases pyridoxal phosphatase (PDXP or chronophin), phosphoglycolate phosphatase (PGP, also termed AUM or glycerol phosphatase) and phospholysine phosphohistidine inorganic pyrophosphate phosphatase (LHPP or HDHD2B). Evidence in support of small metabolite and protein phosphatase activity is discussed in the context of the diversity of their biological functions.     

MAP kinase phosphatases

Mitogen-activated protein MAP kinases are key signal-transducing enzymes that are activated by a wide range of extracellular stimuli. They are responsible for the induction of a number of cellular responses, such as changes in gene expression, proliferation, differentiation, cell cycle arrest and apoptosis. Although regulation of MAP kinases by a phosphorylation cascade has long been recognized as significant, their inactivation through the action of specific phosphatases has been less studied. An emerging family of structurally distinct dual-specificity serine, threonine and tyrosine phosphatases that act on MAP kinases consists of ten members in mammals, and members have been found in animals, plants and yeast. Three subgroups have been identified that differ in exon structure, sequence and substrate specificity.     

Protein tyrosine phosphatases: dual-specificity phosphatases in health and disease

Dual-specificity phosphatases (DSPs) constitute a subfamily of protein tyrosine phosphatases (PTPs) that dephosphorylates phospho-Tyr, phospho-Ser and nonproteinaceous substrates. DSPs are involved in the regulation of both developmental and postnatal essential processes, such as early embryogenesis, placental development and immune responses. Several DSP genes are implicated in familial and sporadic human diseases, including tumor-related, neurological and muscle disorders, and cardiovascular and inflammatory diseases. This association ranges from disease-causative mutations to disease-risk-prone single-nucleotide polymorphisms, promoter methylation or gene duplication (most often in cancer). Deconvolution of the role of DSPs in disease is challenging. The enzymes' activities are regulated at many levels and they form part of extensive, intricate networks with other signaling components. Here, we review current knowledge of the role of cysteine-based PTP-domain DSPs in health and disease, and their suitability as putative therapeutic targets for drugs is discussed.     

Lining the pockets of kinases and phosphatases

The regulation of the activity of kinases and phosphatases is an essential aspect of intracellular signal transduction. Recently determined structures of AGC protein kinases, including isoforms of PKB, PKC, GRK and ROCK, indicate that occupancy of a hydrophobic pocket in the kinase N-lobe by a segment of the protein immediately C terminal to the kinase domain provides a mechanism for regulating kinase activity. In addition, crystal structures of Aurora-A and Aurora-B, which are closely related to AGC family kinases, in complex with their activators, TPX2 and INCENP, respectively, show how allosteric kinase activation is achieved by the binding of the activator protein to an equivalent hydrophobic pocket. Hence, regulation of kinase activity by analogous interactions is a shared regulatory mechanism of these kinases. Two crystal structures have explained the molecular basis of PKA anchoring through its regulatory subunits by members of the AKAP family of scaffold proteins. AKAPs can also interact directly with protein kinase and phosphatase catalytic domains. The crystal structure of the PP1 catalytic subunit in complex with the targeting subunit MYPT1 indicates that there is also scope for intimate phosphatase regulation by scaffold proteins.     

Protein phosphatases of the guinea-pig parotid gland

The nature of protein phosphatases of the guinea-pig parotid gland was investigated. The protein phosphatases were characterized by (a) the use of five different 32P-labelled substrate proteins (phosphorylase a, histone H2B, casein, and the alpha and beta subunits of phosphorylase kinase), (b) their behaviour during ion-exchange chromatography, (c) their relative molecular mass distribution during gel filtration, (d) their sensitivity towards inhibition by inhibitor 2, (e) their ability to be stimulated by protamine and (f) by their behaviour during freezing and thawing in the presence of 2-mercaptoethanol. The following results were obtained. 1. The 'cytosol' (100,000 X g supernatant) contains protein phosphatases of the types 1, 2A and 2B. 2. On the basis of inhibition with inhibitor 2 (1.2 micrograms/ml) the 'cytosolic' phosphorylase phosphatase activity consists to about 40% of protein phosphatase 1 and to about 60% of protein phosphatase 2A. 3. In the cytosol about 80-90% of the protein phosphatases 1 and 2A exist in an inactive state. 4. A 5-10-fold activation can be achieved by ethanol precipitation, which results in the generation of a mixture of forms of low apparent molecular mass of about 30 kDa. 5. Microsome-associated phosphorylase phosphatase activities can be extracted in a highly active state by detergent (1% Triton X-100) or by 0.8 M NaCl. 6. Activity measurements in the presence of inhibitor 2 (1.2 micrograms/ml) indicate that the microsomal activities consist to about 75% of protein phosphatase 1 and to about 25% of protein phosphatase 2A. Activities corresponding to protein phosphatases 2B and 2C could not be detected. 7. The 'microsomal' protein phosphatase activities exhibit lower apparent molecular masses (70 kDa and 30 kDa) than the 'cytosolic' protein phosphatases (about 260 kDa). 8. After ethanol treatment of the microsomal protein phosphatases only activities with apparent molecular masses of about 30 kDa can be detected. These share several similarities with the ethanol-treated cytosolic protein phosphatases. 9. Both cytosolic and microsomal protein phosphatases display activity towards histone H2B and casein.     

Cdc25 phosphatases

Comment on: Thomas Y, et al. Cell Cycle 2010; 9:4338–50.     

Protein tyrosine phosphatases

Insulin receptor signal transduction plays a critical role in regulating pancreatic β-cell function, notably the acute first-phase insulin release in response to glucose. The basis for insulin resistance in pancreatic β-cells is not well understood but may be related to abnormal regulation of tyrosine phosphorylation events, which, in turn, may alter organization of insulin-signaling molecules in space and time. Members of the protein tyrosine phosphatase (PTPase) family are both functionally and structurally diverse; and within the past few years data have emerged from many laboratories that suggest selectivity of the PTPase catalytic domains toward cellular substrates. Of significance, a subset of PTPases has been implicated in the regulation of insulin signaling in a number of insulin-sensitive tissues. Alteration in PTPase expression or activity has been associated with abnormal regulation of tyrosine phosphorylation events and is accompanied by modulation of insulin sensitivity in vivo. Manipulations aimed at reducing expression of physiologically relevant PTPases acting at a step proximal to the insulin receptor are accompanied by normalization of blood glucose levels and improved insulin sensitivity in both normal and diabetic animals. Hence, the development of tissue-specific gene inactivation strategies should facilitate the study of the potential role of PTPases in β-cell insulin signaling transduction.     

Immunological characterization of phosphoprotein phosphatases

Phosphoprotein phosphatases regulate the biological activities of proteins through their involvement in cyclic phosphorylation/dephosphorylation cascades. A variety of multimeric phosphatases have been isolated and grouped into several classes, termed type 1 and types 2A, 2B, and 2C. To elucidate the relationship between the different phosphoprotein phosphatases, highly purified enzymes from soil amoebae, turkey gizzards, bovine heart and brain, and rabbit skeletal muscle and reticulocytes were tested for immunological antigenic relatedness. Two heterologous antibody preparations were employed for this purpose. One was made against an Acanthamoeba type 2A phosphatase and the other was made to bovine brain phosphatase type 2B (calcineurin, holoenzyme). Specific subunit cross-reactivity was examined by protein blot ("Western") analysis. The antibody to the type 2A phosphatase reacted with the catalytic subunits of every type 2 enzyme tested, including both the catalytic and Ca2+-binding subunits of the Ca2+/calmodulin-dependent type 2B phosphatase (calcineurin), bovine cardiac type 2A phosphatase, and turkey gizzard smooth muscle phosphatase-1 (type 2A1). It did not react with any type 1 phosphatase (catalytic subunit or ATP-Mg-dependent). The antigenic relatedness of calcineurin and the bovine cardiac type 2A phosphatase (Mr 38,000) was demonstrated further by protein blot analysis showing that the anti-calcineurin antibody cross-reacted with both enzymes. The mutual cross-reactivity poses an intriguing problem because these enzymes are so different in their molecular structures and modes of regulation. The degree of evolutionary conservation exhibited by the antigenic cross-reactivity of the type 2 enzymes from a broad range of species and tissues suggests a strong selective pressure on maintaining one or more features of these important regulatory enzymes.     

Insulin-receptor phosphotyrosyl-protein phosphatases.

Calmodulin-dependent protein phosphatase has been proposed to be an important phosphotyrosyl-protein phosphatase. The ability of the enzyme to attack autophosphorylated insulin receptor was examined and compared with the known ability of the enzyme to act on autophosphorylated epidermal-growth-factor (EGF) receptor. Purified calmodulin-dependent protein phosphatase was shown to catalyse the complete dephosphorylation of phosphotyrosyl-(insulin receptor). When compared at similar concentrations, 32P-labelled EGF receptor was dephosphorylated at greater than 3 times the rate of 32P-labelled insulin receptor; both dephosphorylations exhibited similar dependence on metal ions and calmodulin. Native phosphotyrosyl-protein phosphatases in cell extracts were also characterized. With rat liver, heart or brain, most (75%) of the native phosphatase activity against both 32P-labelled insulin and EGF receptors was recovered in the particulate fraction of the cell, with only 25% in the soluble fraction. This subcellular distribution contrasts with results of previous studies using artificial substrates, which found most of the phosphotyrosyl-protein phosphatase activity in the soluble fraction of the cell. Properties of particulate and soluble phosphatase activity against 32P-labelled insulin and EGF receptors are reported. The contribution of calmodulin-dependent protein phosphatase activity to phosphotyrosyl-protein phosphatase activity in cell fractions was determined by utilizing the unique metal-ion dependence of calmodulin-dependent protein phosphatase. Whereas Ni2+ (1 mM) markedly activated the calmodulin-dependent protein phosphatase, it was found to inhibit potently both particulate and soluble phosphotyrosyl-protein phosphatase activity. In fractions from rat liver, brain and heart, total phosphotyrosyl-protein phosphatase activity against both 32P-labelled receptors was inhibited by 99.5 +/- 6% (mean +/- S.E.M., 30 observations) by Ni2+. Results of Ni2+ inhibition studies were confirmed by other methods. It is concluded that in cell extracts phosphotyrosyl-protein phosphatases other than calmodulin-dependent protein phosphatase are the major phosphotyrosyl-(insulin receptor) and -(EGF receptor) phosphatases.