Reversible oxidation and inactivation of protein tyrosine phosphatases in vivo

We have investigated the regulation of protein tyrosine phosphatases (PTPs) by reactive oxygen species (ROS) in a cellular environment. We demonstrate that multiple PTPs were reversibly oxidized and inactivated following treatment of Rat-1 cells with H(2)O(2) and that inhibition of PTP function was important for ROS-induced mitogenesis. Furthermore, we show transient oxidation of the SH2 domain containing PTP, SHP-2, in response to PDGF that requires association with the PDGFR. Our results indicate that SHP-2 inhibits PDGFR signaling and suggest a mechanism by which autophosphorylation of the PDGFR occurs despite its association with SHP-2. The data suggest that several PTPs may be regulated by oxidation and that characterization of this process may define novel links between specific PTPs and particular signaling pathways in vivo.     

Regulation of protein tyrosine phosphatases by reversible oxidation

Oxidation of the catalytic cysteine of protein-tyrosine phosphatases (PTP), which leads to their reversible inactivation, has emerged as an important regulatory mechanism linking cellular tyrosine phosphorylation and signalling by reactive-oxygen or -nitrogen species (ROS, RNS). This review focuses on recent findings about the involved pathways, enzymes and biochemical mechanisms. Both the general cellular redox state and extracellular ligand-stimulated ROS production can cause PTP oxidation. Members of the PTP family differ in their intrinsic susceptibility to oxidation, and different types of oxidative modification of the PTP catalytic cysteine can occur. The role of PTP oxidation for physiological signalling processes as well as in different pathologies is described on the basis of well-investigated examples. Criteria to establish the causal involvement of PTP oxidation in a given process are proposed. A better understanding of mechanisms leading to selective PTP oxidation in a cellular context, and finding ways to pharmacologically modulate these pathways are important topics for future research.     

An antibody-based method for monitoring in vivo oxidation of protein tyrosine phosphatases

Regulation of protein tyrosine phosphatases (PTPs) through reversible oxidation of the active site cysteine is emerging as a general, yet poorly characterized, mechanism for control of the activity of this important group of enzymes. This regulatory mechanism was initially described after in vitro treatment of PTPs with oxidizing agents. However, accumulating evidence has substantiated the notion that this mechanism is also operating in vivo, e.g., in association with the transient increase in H(2)O(2) production which occurs after activation of receptor tyrosine kinases. A novel generic antibody-based method for monitoring of PTP oxidation is described. The sensitivity of this strategy has been validated by the demonstration of oxidation of endogenously expressed PTPs after stimulation of cells with growth factors. The method was also instrumental in providing the first evidence for intrinsic differences between PTP domains with regard to sensitivity to oxidation.     

Differential oxidation of protein-tyrosine phosphatases

Oxidation is emerging as an important regulatory mechanism of protein-tyrosine phosphatases (PTPs). Here we report that PTPs are differentially oxidized, and we provide evidence for the underlying mechanism. The membrane-proximal RPTPalpha-D1 was catalytically active but not readily oxidized as assessed by immunoprobing with an antibody that recognized oxidized catalytic site cysteines in PTPs (oxPTPs). In contrast, the membrane-distal RPTPalpha-D2, a poor PTP, was readily oxidized. Oxidized catalytic site cysteines in PTP immunoprobing and mass spectrometry demonstrated that mutation of two residues in the Tyr(P) loop and the WPD loop that reverse catalytic activity of RPTPalpha-D1 and RPTPalpha-D2 also reversed oxidizability, suggesting that oxidizability and catalytic activity are coupled. However, catalytically active PTP1B and LAR-D1 were readily oxidized. Oxidizability was strongly dependent on pH, indicating that the microenvironment of the catalytic cysteine has an important role. Crystal structures of PTP domains demonstrated that the orientation of the absolutely conserved PTP loop arginine correlates with oxidizability of PTPs, and consistently, RPTPmu-D1, with a similar conformation as RPTPalpha-D1, was not readily oxidized. In conclusion, PTPs are differentially oxidized at physiological pH and H(2)O(2) concentrations, and the PTP loop arginine is an important determinant for susceptibility to oxidation.     

Prion protein reduces both oxidative and non-oxidative copper toxicity

The prion protein is a membrane tethered glycoprotein that binds copper. Conversion to an abnormal isoform is associated with neurodegenerative diseases known as prion diseases. Expression of the prion protein has been suggested to prevent cell death caused by oxidative stress. Using cell based models we investigated the potential of the prion protein to protect against copper toxicity. Although prion protein expression effectively protected neurones from copper toxicity, this protection was not necessarily associated with reduction in oxidative damage. We also showed that glycine and the prion protein could both protect neuronal cells from oxidative stress. Only the prion protein could protect these cells from the toxicity of copper. In contrast glycine increased copper toxicity without any apparent oxidative stress or lipid peroxidation. Mutational analysis showed that protection by the prion protein was dependent upon the copper binding octameric repeat region. Our findings demonstrate that copper toxicity can be independent of measured oxidative stress and that prion protein expression primarily protects against copper toxicity independently of the mechanism of cell death.     

Role of oxidative stress and protein oxidation in the aging process

The hypothesis is that the rate of oxygen consumption and the ensuing accrual of molecular oxidative damage constitute a fundamental mechanism governing the rate of aging is supported by several lines of evidence: (i) life spans of cold blooded animals and mammals with unstable basal metabolic rate (BMR) are extended and oxidative damage (OxD) is attenuated by an experimental decrease in metabolic rate; (ii) single gene mutations in Drosophila and Caenorhabditis elegans that extend life span almost invariably result in a generalized slowing of physiological activities, albeit via different mechanisms, affecting a decrease in OxD; (iii) caloric restriction decreases body temperature and OxD; and, (iv) results of studies on the effects of transgenic overexpressions of antioxidant enzymes are generally supportive, but quite ambiguous. It is suggested that oxidative damage to proteins plays a crucial role in aging because oxidized proteins lose catalytic function and are preferentially hydrolyzed. It is hypothesized that oxidative damage to specific proteins constitutes one of the mechanisms linking oxidative stress/damage and age-associated losses in physiological functions.     

Role of protein phosphatases 2C on tolerance to lithium toxicity in the yeast Saccharomyces cerevisiae

Protein phosphatases 2C are a family of conserved enzymes involved in many aspects of the cell biology. We reported that, in the yeast Saccharomyces cerevisiae, overexpression of the Ptc3p isoform resulted in increased lithium tolerance in the hypersensitive hal3 background. We have found that the tolerance induced by PTC3 overexpression is also observed in wild-type cells and that this is most probably the result of increased expression of the ENA1 Na(+)-ATPase mediated by the Hog1 MAP kinase pathway. This effect does not require a catalytically active protein. Surprisingly, deletion of PTC3 (similarly to that of PTC2, PTC4 or PTC5) does not confer a lithium-sensitive phenotype, but mutation of PTC1 does. Lack of PTC1 in an ena1-4 background did not result in additive lithium sensitivity and the ptc1 mutant showed a decreased expression of the ENA1 gene in cells stressed with LiCl. In agreement, under these conditions, the ptc1 mutant was less effective in extruding Li(+) and accumulated higher concentrations of this cation. Deletion of PTC1 in a hal3 background did not exacerbate the halosensitive phenotype of the hal3 strain. In addition, induction from the ENA1 promoter under LiCl stress decreased similarly (50%) in hal3, ptc1 and ptc1 hal3 mutants. Finally, mutation of PTC1 virtually abolishes the increased tolerance to toxic cations provided by overexpression of Hal3p. These results indicate that Ptc1p modulates the function of Ena1p by regulating the Hal3/Ppz1,2 pathway. In conclusion, overexpression of PTC3 and lack of PTC1 affect lithium tolerance in yeast, although through different mechanisms.     

Sensors for toxicity of chemicals and oxidative stress based on electrochemical catalytic DNA oxidation

Films of DNA, enzymes, polyions, and catalytic redox polyions of nanometer thickness on electrodes can provide active elements for sensors for screening the toxicity of chemicals and their metabolites, and for oxidative stress. The unifying feature of this approach involves layer-by-layer electrostatic assembly of films designed to detect DNA damage. Films containing DNA and enzymes enable detection of structural damage to DNA as a basis for toxicity screening. These films bioactivate chemicals to their metabolites, which can then react with DNA, mimicking toxicity pathways in the human liver. Metallopolyions that catalyze DNA oxidation can be incorporated into DNA/enzyme films leading to "reagentless" sensors. These sensors are suitable for detecting relative DNA damage rates in <5 min of the enzyme reactions. Films of the osmium polymer [Os(bpy)(2)(PVP)(10)Cl](+) [poly(vinylpyridine), PVP] can be used to monitor DNA oxidation selectively. Such films may be applicable to determination of oxidized DNA as a clinical biomarker for oxidative stress. Inclusion of the analogous ruthenium metallopolymer in the sensor provides a monitor for oxidation of other nucleobases.     

Novel protein phosphatases in yeast.

During the last decade several novel yeast genes encoding proteins related to the PPP family of Ser/Thr protein phosphatases have been discovered and their functional characterization initiated. Most of these novel phosphatases display intriguing structural features and/or are involved in a number of important functions, such as cell cycle regulation, protein synthesis and maintenance of cellular integrity. While in some cases these genes appear to be restricted to fungi, in others similar proteins can be found in higher eukaryotes. This review will summarize the latest advances in our understanding about how these phosphatases are regulated and fulfil their functions in the yeast cell.     

Bax-like protein Drob-1 protects neurons from expanded polyglutamine-induced toxicity in Drosophila

Bcl-2 family proteins regulate cell death through the mitochondrial apoptotic pathway. Here, we show that the Drosophila Bax-like Bcl-2 family protein Drob-1 maintains mitochondrial function to protect cells from neurodegeneration. A pan-neuronal knockdown of Drob-1 results in lower locomotor activity and a shorter lifespan in adult flies. Either the RNAi-mediated downregulation of Drob-1 or overexpression of Drob-1 antagonist Buffy strongly enhances the polyglutamine-induced accumulation of ubiquitinated proteins and subsequent neurodegeneration. Furthermore, ectopic expression of Drob-1 suppresses the neurodegeneration and premature death of flies caused by expanded polyglutamine. Drob-1 knockdown decreases cellular ATP levels, and enhances respiratory inhibitor-induced mitochondrial defects such as loss of membrane potential (Deltapsim), morphological abnormalities, and reductions in activities of complex I+III and complex II+III, as well as cell death. Taken together, these results suggest that Drob-1 is essential for neuronal cell function, and that Drob-1 protects neurons from expanded polyglutamine-mediated neurodegeneration through the regulation of mitochondrial homeostasis.     

Comparison of protein oxidation and aldehyde formation during oxidative stress in isolated mitochondria

Oxidative stress is known to cause oxidative protein modification and the generation of reactive aldehydes derived from lipid peroxidation. Extent and kinetics of both processes were investigated during oxidative damage of isolated rat liver mitochondria treated with iron/ascorbate. The monofunctional aldehydes 4-hydroxynonenal (4-HNE), n-hexanal, n-pentanal, n-nonanal, n-heptanal, 2-octenal, 4-hydroxydecenal as well as thiobarbituric acid reactive substances (TBARS) were detected. The kinetics of aldehyde generation showed a lag-phase preceding an exponential increase. In contrast, oxidative protein modification, assessed as 2,4-dinitrophenylhydrazine (DNPH) reactive protein-bound carbonyls, continuously increased without detectable lag-phase. Western blot analysis confirmed these findings but did not allow the identification of individual proteins preferentially oxidized. Protein modification by 4-HNE, determined by immunoblotting, was in parallel to the formation of this aldehyde determined by HPLC. These results suggest that protein oxidation occurs during the time of functional decline of mitochondria, i.e. in the lagphase of lipid peroxidation. This protein modification seems not to be caused by 4-HNE.     

Role of protein phosphatases in hypoxic preconditioning

To find a protein kinase C (PKC)-independent preconditioning mechanism, hypoxic preconditioning (HP; i.e., 10-min anoxia and 10-min reoxygenation) was applied to isolated rat hearts before 60-min global ischemia. HP led to improved recovery of developed pressure and reduced end-diastolic pressure in the left ventricle during reperfusion. Protection was unaffected by the PKC inhibitor bisindolylmaleimide (BIM; 1 micromol/l). It was abolished by the inhibitor of protein phosphatases 1 and 2A cantharidin (20 or 5 micromol/l) and partially enhanced by the inhibitor of protein phosphatase 2A okadaic acid (5 nmol/l). In adult rat cardiomyocytes treated with BIM and exposed to 60-min simulated ischemia (anoxia, extracellular pH 6.4), HP led to attenuation of anoxic Na(+)/Ca(2+) overload and of hypercontracture, which developed on reoxygenation. This protection was prevented by treatment with cantharidin but not with okadaic acid. In conclusion, HP exerts PKC-independent protection on ischemic-reperfused rat hearts and cardiomyocytes. Protein phosphatase 1 seems a mediator of this protective mechanism.     

Uncoupling protein 2 protects dopaminergic neurons from acute 1,2,3,6-methyl-phenyl-tetrahydropyridine toxicity

Oxidative stress is implicated in the death of dopaminergic neurons in sporadic forms of Parkinson's disease. Because oxidative stress can be modulated endogenously by uncoupling proteins (UCPs), we hypothesized that specific neuronal expression of UCP2, one member of the UCP family that is rapidly induced in the CNS following insults, could confer neuroprotection in a mouse model of Parkinson's disease. We generated transgenic mice overexpressing UCP2 in catecholaminergic neurons under the control of the tyrosine hydroxylase promoter (TH-UCP2). In these mice, dopaminergic neurons of the substantia nigra showed a twofold elevation in UCP2 expression, elevated uncoupling of their mitochondria, and a marked reduction in indicators of oxidative stress, an effect also observed in the striatum. Upon acute exposure to 1,2,3,6-methyl-phenyl-tetrahydropyridine, TH-UCP2 mice showed neuroprotection and retention of locomotor functions. Our data suggest that UCP2 may represent a drug target for slowing the progression of Parkinson's disease.     

Activation of double-stranded RNA-activated protein kinase by mild impairment of oxidative metabolism in neurons

Thiamine (vitamin B1) deficiency (TD) causes mild and chronic impairment of oxidative metabolism and induces neuronal death in specific brain regions. The mechanisms underlying TD-induced cell death, however, remain unclear. The double-stranded RNA-activated protein kinase (PKR), has been well known for its anti-viral function. Upon activation by viral infection or double-stranded RNA, PKR phosphorylates its substrate, the α-subunit of eukaryotic initiation factor-2 (eIF2α), leading to inhibition of translation. In response to various cellular stresses, PKR can also be stimulated by its protein activators, or its mouse homologue, PKR activator (RAX). We demonstrated that TD in mice induced phosphorylation of PKR at Thr446 and Thr451 and phosphorylation of eIF2α at Ser51 in the cerebellum and the thalamus. TD caused phosphorylation of PKR and eIF2α, as well as nuclear translocation of PKR in primary cultures of cerebellar granule neurons. PKR phosphorylation is necessary for its nuclear translocation because TD failed to induce nuclear translocation of a T446A/T451A PKR mutant. Both PKR inhibitor and dominant-negative PKR mutant protected cerebellar granule neurons against TD-induced cell death. TD promoted the association between RAX and PKR. Antioxidant vitamin E dramatically decreased the RAX/PKR association and ameliorated TD-induced cell death. Our results indicate that TD-induced neuronal death is at least partially mediated by the activation of PKR.     

Identification of protein phosphatases 1 and 2B as ribosomal protein S6 phosphatases in vitro and in vivo

Protein phosphatases 1 and 2B from rabbit skeletal muscle were found to catalyze the dephosphorylation of ribosomal protein S6 in vitro. Phosphorylation of protein phosphatase-1 by the transforming protein of Rous sarcoma virus, pp60v-src, abolished S6 dephosphorylation by the purified enzyme. Analysis of the dephosphorylation of phosphorylase a and phosphorylase kinase in Xenopus oocyte extracts and after microinjection indicated the presence of oocyte enzymes similar to protein phosphatases-1 and -2B. Studies with 32P-labeled 40 S ribosomal subunits suggested that these enzymes were functioning as S6 phosphatases in oocytes. These findings support the hypothesis that regulation of protein phosphatase activity may be involved in the increase in S6 phosphorylation observed after mitogenic stimulation.     

The complex nature of protein phosphatases

Protein phosphatases are integrally associated with the regulation of cellular signaling. The mechanisms underlying the specific regulatory roles are likely to be unique to each cell system. Nevertheless, analysis of phosphatase regulation in a number of systems has identified phosphatase targeting through association with a wide range of binding partners to be a fundamental mechanism of regulation. Using protein phosphatase 2A (PP2A) as an example, this snapshot summarizes these fundamental mechanisms of protein phosphatase regulation.