Phosphatases protein

TARGET PROTEINS FOR D1 RECEPTOR-REGULATED cAMP PATHWAY 3.3.1. cAMP-dependent phosphoproteins in the striatum 

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As examples of applications, we present the overall accuracy of predicted ionization constants for about 50 groups in 4 proteins, changes in the average charge of bovine pancreatic trypsin inhibitor at pH 7 along a molecular dynamics trajectory, and finally, we discuss some preliminary results obtained for protein kinases and protein phosphatases. 

The last part of this account will be devoted to protein kinases and protein phosphatases and some recent results we have obtained for them. Protein kinases and phosphatases are signaling biomolecules that control the level of phosphorylation and dephosphorylation of tyrosine, serine or threonine residues in other proteins, and by this means regulate a variety of fundamental cellular processes including cell growth and proliferation, cell cycle and cytoskeletal integrity. 

Fig. 4. Ribbon model of protein kinase with peptide substrate and Mn2ATP (left) and protein phosphatase (right)...

At the molecular level, microcystins are potent inhibitors of protein phosphatases 1 and 2A. The activity of protein phosphatases can be determined by measuring... 

After screening for toxicity, identification and/or quantification assays may need to be carried out if the screening method is not specific for the cyanobacterial toxin(s) under investigation. Suitable assays for these purposes include the physicochemical assays, HPLC, MS, and CE, and to some extent the immunoassays and protein phosphatase inhibition assays summarized in Section 2. 

The ability to identify and quantify cyanobacterial toxins in animal and human clinical material following (suspected) intoxications or illnesses associated with contact with toxic cyanobacteria is an increasing requirement. The recoveries of anatoxin-a from animal stomach material and of microcystins from sheep rumen contents are relatively straightforward. However, the recovery of microcystin from liver and tissue samples cannot be expected to be complete without the application of proteolytic digestion and extraction procedures. This is likely because microcystins bind covalently to a cysteine residue in protein phosphatase. Unless an effective procedure is applied for the extraction of covalently bound microcystins (and nodiilarins), then a negative result in analysis cannot be taken to indicate the absence of toxins in clinical specimens. Furthermore, any positive result may be an underestimate of the true amount of microcystin in the material and would only represent free toxin, not bound to the protein phosphatases. Optimized procedures for the extraction of bound microcystins and nodiilarins from organ and tissue samples are needed. 

Specificity of the assay depends on the specificity (cross-reactivity) of the antibodies. Of the known cyanobacterial toxins, only hepatotoxins are detected and are, therefore, able to be screened for by protein phosphatase inhibition. 

It is obvious from the provisional risk assessment values for microcystins, and, being of the same order of magnitude of mammalian toxicity, similar values may be calculated for the cyanobacterial neurotoxins, that sensitive detection methods are required to detect these low concentrations of toxins. Of the biological methods of detection discussed earlier, the mouse and invertebrate bioassays are not sensitive enough without concentration of water samples, in that they are only able to detect mg of microcystins per litre. Only the immunoassays (ng-/rg 1 and the protein phosphatase inhibition assays (ng O... 

FIGURE 15.2 Enzymes regulated by covalent modification are called interconvertible enzymes. The enzymes protein kinase and protein phosphatase, in the example shown here) catalyzing the conversion of the interconvertible enzyme between its two forms are called converter enzymes. In this example, the free enzyme form is catalytically active, whereas the phosphoryl-enzyme form represents an inactive state. The —OH on the interconvertible enzyme represents an —OH group on a specific amino acid side chain in the protein (for example, a particular Ser residue) capable of accepting the phosphoryl group. 

Dephosphorylation of glycogen phosphorylase is carried out by phospho-protein phosphatase 1. The action of phosphoprotein phosphatase 1 inactivates glycogen phosphorylase. 

R. W. MacKintosh, K. N. Dalby, D. G. Campbell, P. T. W. Cohen, P. Cohen and C. MacKintosh, The cyanobacterial toxin microcystin binds covalently to cysteine-273 on protein phosphatase 1 , FEBS Lett. 371 236-240 (1995). 

A secondary metabolite produced by Tolypocladium inflation. This fungus was initially isolated in a soil sample collected in Norway. Cyclosporin A is a cyclic undecapeptide. Inside cells, cyclosporine A binds its immunophillin receptor known as cyclophillin. Like the FK506-FKBP12 complex, cyclosporin A-cyclophillin binds and inhibits the protein phosphatase calcineurin. 

FKBP12 is a member of immunophilin family that has prolyl isomerase activity and is related to the cyclophi-lins in function. FKBP12 binds immunosuppressant molecule FK506 (tacrolimus). The FBKP-FK506 complex inhibits calcineurin, a protein phosphatase, thus blocking signal transduction in the T-lymphocyte... 

Immunosuppressive Agents Protein Phosphatases Ryanodine Receptor... 

Cyclosporine A (CsA) is a water-insoluble cyclic peptide from a fungus composed of 11 amino acids. CsA binds to its cytosolic receptor cyclophilin. The CsA/cyclophilin complex reduces the activity of the protein phosphatase calcineurin. Inhibition of this enzyme activity interrupts antigen receptor-induced activation and translocation of the transcription factor NEAT to the nucleus which is essential for the induction of cytokine synthesis in T-lymphocytes. 

Signaling by PKC is terminated by concentrations of its ligands dropping to basal levels (i.e., Ca2+ and diacylglycerol) and by dephosphorylation of the three processing sites. Dephosphorylation is controlled, in part, by a recently discovered hydrophobic phosphorylation motif phosphatase. This phosphatase, PHLPP (for PH domain Leucine-rich repeat Protein Phosphatase) dephosphorylates conventional and novel PKC isozymes, initiating their downregulation. 

After their synthesis (translation), most proteins go through a maturation process, called post-translational modification that affects their activity. One common post-translational modification of proteins is phosphorylation. Two functional classes of enzymes mediate this reversible process protein kinases add phosphate groups to hydroxyl groups of serine, threonine and tyrosine in their substrate, while protein phosphatases remove phosphate groups. The phosphate-linking... 

Protein phosphatases are several classes of enzymes that catalyze the hydrolysis of phospho-amino acids within a peptide or protein, thus resulting in dephosphorylation. 

Protein phosphatases are classified according to their activity toward phospho-amino acids they act on (Fig. 1). Nomenclature is independent of regulation simply because stimuli were unknown. Protein phosphatases hydrolyzing O-phospho-monoesters are currently subdivided into two major classes (i) phosphatases acting on phosphoserine (pSer) and phosphothreonine (pThr), and (ii) the second class... 

Protein Phosphatases. Figure 1 The diversity of protein phosphatases. 

Protein Phosphatases. Figure 2 Families and subtypes of serine/threonine protein phosphatases. 

PP protein phosphatases PPP phospho protein phosphatases PPM protein phosphatases Mg2+-dependent. 

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