Crystal Structure of the Tumor-promoter Okadaic Acid Bound to Protein Phosphatase-1

Maynes, Jason T.; Bateman, Katherine S.; Cherney, M.M.; Das, Amit Kumar; Luu, Hue Anh; Holmes, Charles F.B.; James, Michael N.G.

doi:10.1074/jbc.m107656200

Cited by 153 publications

(154 citation statements)

References 36 publications

(36 reference statements)

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“…Egloff et al (1995) investigated the nature and function of the two metal ions (Mn 2+ and Fe 2+ or Fe 3+ ) and reported that metal ions promote hydrolysis reactions by activating water molecules and stabilizing nucleophilic hydroxide and oxide ions. Figure 14 shows the molecular surface of the catalytic subunit of PP1-microcystin-LR complex (Goldberg et al 1995), and similar crystal structures of the molecular complex of catalytic subunit of PP1-okadaic acid (Maynes et al 2001), PP1-calyculin A (Kita et al 2002), and PP1-motuporin (Maynes et al 2006) have also been reported.…”

Section: Nodularinmentioning

confidence: 97%

“…As Uemura and Hirata (1989) suggested (Fig. 13), a hydrogen bond formed by a cyclic structure between the C-1 acid and the C-24 (Uemura and Hirata 1989) hydroxyl group was confirmed in both free okadaic acid and the PP1-okadaic acid complex (Maynes et al 2001). The acid motif in okadaic acid accepts a hydrogen bond from the hydroxyl group of Tyr 272 in PP1, and the esterification or removal of the acidic moiety in okadaic acid results in elimination of its inhibitory activity.…”

Section: Okadaic Acidmentioning

confidence: 99%

“…They found that microcystin-LR binds to the catalytic subunit of PP1 through the three regions of the surface, and the long hydrophobic Adda side chain was packed into the hydrophobic groove. Although covalent linkage between a methyldehydroalanine residue in microcystin-LR and the Sγ of Cys 273 is present, it is not the primary cause of inhibition of PP1 by microcystin-LR (Maynes et al 2001). The carboxyl group of d-erythro-β-methylaspartic acid was also found to interact with Tyr 134 (Maynes et al 2001(Maynes et al , 2006.…”

Section: Microcystin-lrmentioning

confidence: 99%

“…Although covalent linkage between a methyldehydroalanine residue in microcystin-LR and the Sγ of Cys 273 is present, it is not the primary cause of inhibition of PP1 by microcystin-LR (Maynes et al 2001). The carboxyl group of d-erythro-β-methylaspartic acid was also found to interact with Tyr 134 (Maynes et al 2001(Maynes et al , 2006. Interaction between microcystin-LR and the C-terminal groove occurs at the loop connecting the β12-β13, where the leucine side chain in microcystin-LR is packed close to the side chain of Tyr 272 (Goldberg et al 1995).…”

Section: Microcystin-lrmentioning

confidence: 99%

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Developmental Biology of Neoplastic Growth

Macieira‐Coelho¹

2005

Progress in Molecular and Subcellular Biology

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Section: Nodularinmentioning

confidence: 97%

Section: Okadaic Acidmentioning

confidence: 99%

Section: Microcystin-lrmentioning

confidence: 99%

Section: Microcystin-lrmentioning

confidence: 99%

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Developmental Biology of Neoplastic Growth

Macieira‐Coelho¹

2005

Progress in Molecular and Subcellular Biology

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“…1A). 9,15,16 The general lack of inhibition exhibited by the PPP-family members PP2B and PP7 in the presence of these compounds, coupled with differential inhibition of the remaining PPP-family enzymes by select toxins, has made these small molecules invaluable tools in protein phosphatase research by helping implicate distinct protein phosphatases in various cellular processes. Recently, we reported two additional PPPfamily protein phosphatases from A. thaliana (AtSLP1 and -2 phosphatases) that demonstrated complete insensitivity to inhibition by both microcystin and okadaic acid, with AtSLP1 exhibiting slight enzymatic activation.…”

Section: Introductionmentioning

confidence: 99%

Okadaic acid and microcystin insensitive PPP-family phosphatases may represent novel biotechnology targets

Uhrig

Moorhead²

2011

Plant Signaling & Behavior

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R eversible protein phosphorylation is of central importance to the proper cellular functioning of all living organisms. Catalyzed by the opposing reactions of protein kinases and phosphatases, dysfunction in reversible protein phosphorylation can result in a wide variety of cellular aberrations. In eukaryotic organisms there exists four classes of protein phosphatases, of which the PPP-family protein phosphatases have documented susceptibility to a range of protein and small molecule inhibitors. These inhibitors have been of great importance to the biochemical characterization of PPP-family protein phosphatases since their discovery, but also maintain in natura biological significance with their endogenous regulatory properties (protein inhibitors) and toxicity (small molecule inhibitors). Recently, two unique PPP-family protein phosphatases, named the Shewanella-like protein phosphatases (SLP phosphatases), from Arabidopsis thaliana were characterized and found to be phylogenetically similar to the PPP-family protein phosphatases protein phosphatase 1 (PP1) and protein phosphatase 2A (PP2A), while completely lacking sensitivity to the classic PPP-family phosphatase small molecule inhibitors okadaic acid and microcystin-LR. SLP phosphatases were also found to be absent in metazoans, but present in a wide range of bacteria, fungi and protozoa responsible for human disease. The unique biochemical properties and evolutionary heritage of SLP phosphatases suggests they could not only be potential biotechnology targets for agriculture, but may also prove to be

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Phosphatases

Hengge

Chu

2010

Encyclopedia of Catalysis

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Phosphatases are enzymes that catalyze the hydrolysis of a phosphate monoester, or, in other words, the phosphoryl transfer from an ester substrate to water. Some phosphatases, utilizing a binuclear metal center, accomplish this reaction in a single step. Others, some of which also utilize two‐metal ion catalysis and some of which do not, first form a phosphoenzyme intermediate, which is hydrolyzed by attack of water in a second step. Protein‐tyrosine phosphatases utilize a conserved cysteine residue and form a phosphocysteine intermediate. Alkaline phosphatases utilize two zinc ions and form a phosphoserine intermediate. The protein serine/threonine phosphatases and the purple acid phosphatases have a dinuclear metal center and catalyze the direct transfer of the phosphoryl group to a metal‐coordinated hydroxide. A number of phosphatases have been found capable of catalyzing other hydrolysis reactions, such as those of sulfate esters, or of phosphate and phosphonate diesters. Such so‐called promiscuous activities arise from the ability of the enzymes to stabilize a trigonal bipyramidal transition state, which is common to the reaction of its native substrate as well as the alternate substrates.

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Crystal Structure of the Tumor-promoter Okadaic Acid Bound to Protein Phosphatase-1

Cited by 153 publications

References 36 publications

Developmental Biology of Neoplastic Growth

Developmental Biology of Neoplastic Growth

Okadaic acid and microcystin insensitive PPP-family phosphatases may represent novel biotechnology targets

Phosphatases

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