Phosphatases phosphate phosphatase

Phosphatase Phosphatase enzymes Phosphatase tests Phosphatation Phosphate... 

Lipid phosphate phosphohydrolases (LPPs), formerly called type 2 phosphatidate phosphohydrolases (PAP-2), catalyse the dephosphorylation of bioactive phospholipids (phosphatidic acid, ceramide-1-phosphate) and lysophospholipids (lysophosphatidic acid, sphingosine-1-phosphate). The substrate selectivity of individual LPPs is broad in contrast to the related sphingosine-1-phosphate phosphatase. LPPs are characterized by a lack of requirement for Mg2+ and insensitivity to N-ethylmaleimide. Three subtypes (LPP-1, LPP-2, LPP-3) have been identified in mammals. These enzymes have six putative transmembrane domains and three highly conserved domains that are characteristic of a phosphatase superfamily. Whether LPPs cleave extracellular mediators or rather have an influence on intracellular lipid phosphate concentrations is still a matter of debate. 

Several observations regarding this aspect have been published, and are briefly mentioned here. 5,6-Dideoxy-6-C-phosphono-D-arabino-hexofuranose (135), an isosteric phosphonate analog of D-arabinose 5-phosphate, is apparently converted, in the presence of enolpyruvate phosphate, into 3,8,9-trideoxy-9-C-phosphono-D-mcmno-2-nonulosonic acid (136) under catalysis by KDO 8-phosphate synthetase from Escherichia coli K 235. Compound 136, an isosteric phosphonate analog of KDO 8-phosphate, is a product inhibitor of the synthetase, and, by the nature of the phosphonate group, is not subject to dephosphorylation as catalyzed by KDO 8-phosphate phosphatase156 (see Scheme 40). Compound 119 (see Scheme 33) is a weak inhibitor of KDO 8-phosphate synthetase.81 KDO inhibits KDO 8-phosphate phosphatase,139 and D-ribose 5-phosphate has an inhibitory... 

The on-bead assay was conducted according to Scheme 3.19, which shows the chain of events, which leads to a colorimetric response, when an oligosaccharide binds effectively to the B. purpurea lectin. The lectin was covalently linked to biotin, a small molecule with an extremely high affinity for streptavidin. The bead-lectin-biotin conjugates were then exposed to streptavidin, linked to the enzyme alkaline phosphatase. Alkaline phosphatase hydrolyses phosphate esters [e.g., 5-bromo-4-chloro-3-indolyl phosphate (BCIP), 110]. When the 5-bromo-4-chloro-3-hydroxyindole (111) is released, in the presence of nitro blue tetrazolium (NBT), it forms a dark purple, insoluble dye, thus staining beads where there was a favorable binding interaction. 

Phosphates of pharmaceutical interest are often monoesters (Sect. 9.3), and the enzymes that are able to hydrolyze them include alkaline and acid phosphatases. Alkaline phosphatase (alkaline phosphomonoesterase, EC 3.1.3.1) is a nonspecific esterase of phosphoric monoesters with an optimal pH for catalysis of ca. 8 [140], In the presence of a phosphate acceptor such as 2-aminoethanol, the enzyme also catalyzes a transphosphorylation reaction involving transfer of the phosphoryl group to the alcohol. Alkaline phosphatase is bound extracellularly to membranes and is widely distributed, in particular in the pancreas, liver, bile, placenta, and osteoplasts. Its specific functions in mammals remain poorly understood, but it seems to play an important role in modulation by osteoplasts of bone mineralization. 

A murine SIP phosphatase gene, which encodes a 430 amino acid (47.7kDa) protein, has recently been cloned (Mandala et al, 2000). This enzyme bears similarity to a family of lipid phosphate phosphatases (LPPs) (Brindley and Waggoner, 1998) in that it has invariant residues within the three domains of the common predicted catalytic site ((K-X6-RP)-Xu.37-(S-X-H)-X4o.46-(R-Xs-H-X3-D)) although the spacing between the domains differs from the LPPs. In contrast to LPPs, SIP phosphatase is highly... 

Alderton, F.A., Darroch, P.I., Sambi, B., McKie, A., Pyne, N.J. and Pyne, S., 2001, G-protein-coupled receptor signaling to p42/p44 mitogen-activated protein kinase is attenuated by Upid phosphate phosphatases 1,1a and 2 in HEK 293 cells, J. Biol. Chem. 276 13452-13460. 

Mandala, S.M., 2001, Sphingosine l-phosphate phosphatases. Prostaglandins Lipid Mediators 64 143-156. 

An exo-linker according to Fig. 10.1 must contain an enzyme labile group R, which is recognized and attacked by the biocatalyst Possible combinations could be phenylacetamide/penicillin amidase, ester/esterase, monosaccharide/glycosid-ase, phosphate/phosphatase, sulfate/sulfatase and peptides/peptidases [41]. The following systems have been worked out (Tab. 10.2). 

SG7F10.14C StrO 259 30135 Af-Amidino-scy/to -inosamine-4 phosphate phosphatase... 

HISTIDINOL-PHOSPHATE PHOSPHATASE HISTIDYL-tRNA SYNTHETASE HISTONE KINASE Hofmann rule,... 

GLYCOGEN PHOSPHORYLASE HISTIDINOL-PHOSPHATE PHOSPHATASE myo-INOSITOL 1-MONOPHOSPHATASE... 

FIGURE 20-27 Regulation of sucrose phosphate synthase by phosphorylation. A protein kinase (SPS kinase) specific for sucrose phosphate synthase (SPS) phosphorylates a Ser residue in SPS, inactivating it a specific phosphatase (SPS phosphatase) reverses this inhibition. The kinase is inhibited allosterically by glucose 6-phosphate, which also activates SPS allosterically. The phosphatase is inhibited by Pi, which also inhibits SPS directly. Thus when the concentration of glucose 6-phosphate is high as a result of active photosynthesis, SPS is activated and produces sucrose phosphate. A high P, concentration, which occurs when photosynthetic conversion of ADP to ATP is slow, inhibits sucrose phosphate synthesis. 

Many enzymes are regulated by covalent modification, most frequently by the addition or removal of phosphate groups from specific serine, threonine, or tyrosine residues of the enzyme. In the fed state, most of the enzymes regulated by covalent modification are in Ihe dephosphorylated form and are active (see Figure 24.2). Three exceptions are glycogen phosphorylase (see p. 129), fructose bis-phosphate phosphatase-2 (see p. 98), and hormone-sensitive lipase of adipose tissue (see p. 187), which are inactive in their dephosphorylated state. 

Dolichyl phosphate phosphatase has been described in animal tissues,74-76 and it is possibly responsible for the free dolichol found in tissues. This free dolichol can be rephosphorylated by a dolichol kinase using cytidine triphosphate (CTP) as phosphoric donor,77-78 or acylated by a dolichol acyltransferase79 (see Scheme 1). 

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