Phosphatase E. coli

OtsA OtsB Trehalose-6-P synthase Trehalose-6-P phosphatase E. coli Trehalose Tobacco Rice Increased biomass, morphogenesis, growth 52, 53... 

In contrast, another group35 found that extracts of E. coli contained a mixture of pentulose phosphates at a concentration near 0.3 nmol per mg of the dry weight of cells. The sugars were estimated by gas chromatography-mass spectrometry after treatment of the extract with phosphatase followed by silylation, or borohydride reduction and acetylation. Furthermore, a partially purified preparation from these extracts catalyzed the synthesis of 1-deoxypentulose... 

HARKER M and BRAMLEY P M (1999) Expression of l-deoxy-D-xylulose-5-phosphatases in E. coli increases carotenoid and ubiquinone biosynthesis , FEBSLett, 448, 115-19. 

While having three metal ions in an enzyme active site is uncommon, it is not unique to PLCBc. The well-known alkaline phosphatase from E. coli (APase) contains two zinc ions and a magnesium ion [67], whereas the a-toxin from Clostridiumperfringens [68]. and the PI nuclease from Penicillium citrinum [69] each contain three zinc ions. Indeed, the zinc ions and coordinating ligands of PI nuclease bear an uncanny resemblance to those of PLCBc as the only differ-... 

Enzyme labels are usually coupled to secondary antibodies or to (strept)avidin. The latter is used for detection of biotinylated primary or secondary antibodies in ABC methods (see Sect. 6.2.1). Enzyme labels routinely used in immunohisto-chemistry are horseradish peroxidase (HRP) and calf intestinal alkaline phosphatase (AP). Glucose oxidase from Aspergillus niger and E. coli (3-galactosidase are only rarely applied. 

Enzymatic markers used in immunohistochemistry Horseradish peroxidase (HRP) and calf intestinal or E.coli alkaline phosphatase (AP). Glucose oxidase from Aspergillus niger and E.coli /3-galactosidase are only rarely applied. 

The long-lived phosphorescence of the tryptophan in alkaline phosphatase is unusual. Horie and Vanderkooi examined whether its phosphorescence could be detected in E. coli strains which are rich in alkaline phosphatase.(89) They observed phosphorescence at 20°C with a lifetime of 1.3 s, which is comparable to the lifetime of purified alkaline phosphatase (1.4 s). Long-lived luminescence was not observed from strains deficient in alkaline phosphatase. The temperature dependence of tryptophan phosphorescence in the living cells was slightly different from that for the purified enzyme, indicating an environmental effect. 

T. Horie and J. M. Vanderkooi, Phosphorescence of alkaline phosphatase of E. coli in vitro and in situ, Biochim. Biophys. Acta 670, 290-290 (1981). 

Isolation of alkaline phosphatase from Escherichia coli in which 85% of the proline residues were replaced by 3,4-dehydro-proline affected the heat lability and ultraviolet spectrum of the protein but the important criteria of catalytic function such as the and were unaltered (12). Massive replacement of methionine by selenomethionine in the 0-galactosidase of E. coli also failed to influence the catalytic activity. Canavanine facilely replaced arginine in the alkaline phosphatase of this bacterium at least 13 and perhaps 20 to 22 arginyl residues were substituted. This replacement by canavanine caused subunit accumulation since the altered subunits did not dimerize to yield the active enzyme (21). Nevertheless, these workers stated "There was also formed, however, a significant amount of enzymatically active protein in which most arginine residues had been replaced by canavanine." An earlier study in which either 7-azatryptophan or tryptazan replaced tryptophan resulted in active protein comparable to the native enzyme (14). 

The X-ray crystal structure of the inorganic phosphate (an inhibitor) complex of alkaline phosphatase from E. coli (9) showed that the active center consists of a Zn2Mg(or Zn) assembly, where the two zinc(II) atoms are 3.94 A apart and bridged by the bidentate phosphate (which suggests a phosphomonoester substrate potentially interacting with two zinc(II), as depicted in Fig. 2), and the Mg (or the third Zn) is linked to one atom of the zinc pair by an aspartate residue at a distance... 

Oudot, C. Gortay, J.C. Blanche , C. Laporte, D.C. Di Pietro, A. Cozzone, A.J. Jault, J.M. The catalytic" triad of isocitrate dehydrogenase kinase/ phosphatase from E. coli and its relationship with that found in eukaryotic protein kinases. Biochemistry, 40, 3047-3055 (2001)... 

Some bacteria, including E. coli, have the full complement of enzymes for the glyoxylate and citric acid cycles in the cytosol and can therefore grow on acetate as their sole source of carbon and energy. The phosphoprotein phosphatase that activates isocitrate dehydrogenase is stimulated by intermediates of the citric acid cycle and glycolysis and by indicators of reduced cellular energy supply (Fig. 16-23). The same metabolites inhibit the protein kinase activity of the bifunctional polypeptide. Thus, the accumulation of intermediates of... 

Considerable ingenuity was required in both the synthesis of these chiral compounds695 697 and the stereochemical analysis of the products formed from them by enzymes.698 700 In one experiment the phospho group was transferred from chiral phenyl phosphate to a diol acceptor using E. coli alkaline phosphatase as a catalyst (Eq. 12-36). In this reaction transfer of the phospho group occurred without inversion. The chirality of the product was determined as follows. It was cyclized by a nonenzymatic in-line displacement to give equimolar ratios of three isomeric cyclic diesters. These were methylated with diazomethane to a mixture of three pairs of diastereoisomers triesters. These dia-stereoisomers were separated and the chirality was determined by a sophisticated mass spectrometric analysis.692 A simpler analysis employs 31P NMR spectroscopy and is illustrated in Fig. 12-22. Since alkaline phosphatase is relatively nonspecific, most phosphate esters produced by the action of phosphotransferases can have their phospho groups transferred without inversion to 1,2-propanediol and the chirality can be determined by this method. 

The alkaline phosphatases are found in bacteria, fungi, and higher animals but not in higher plants. In E. coli alkaline phosphatase is concentrated in the peri-plasmic space. In animals it is found in the brush border of kidney cells, in cells of the intestinal mucosa, and in the osteocytes and osteoblasts of bone. It is almost absent from red blood cells, muscle, and other tissues which are not involved extensively in transport of nutrients. 

The alkaline phosphatase of E. coli is a dimer of 449-residue subunits which requires Zn2+, is allo-sterically activated by Mg2+, and has a pH optimum above 8.667/708 711 At a pH of 4, incubation of the enzyme with inorganic phosphate leads to formation of a phosphoenzyme. Using 32P-labeled phosphate, it was established that the phosphate becomes attached in ester linkages to serine 102. The same active site sequence Asp-Ser-Ala is found in mammalian alkaline phosphatases. These results, as well as the stereochemical arguments given in Section 2, suggest a double-displacement mechanism of Eq. 12-38 ... 

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