Purification of a protein phosphatase from chloroplast stroma capable of dephosphorylating the light-harvesting complex-II.

A protein phosphatase was purified from the stroma of Pea (Pisum sativum L.) chloroplasts that is capable of dephosphorylating synthetic phosphopeptides. Following chromatographic purification of greater than 400-fold, two-dimensional electrophoresis indicated that the stromal protein phosphatase is a 29-kD protein. A similar molecular size was determined for the protein-phosphatase activity using gel-permeation chromatography, indicating that the stromal protein phosphatase is probably a monomer. The purified enzyme was able to dephosphorylate synthetic phosphopeptides, which mimic the thylakoid light-harvesting complex II (LHC-II) N terminus, as well as LHC-II in thylakoid membranes, but did not dephosphorylate the major 64-kD phosphoprotein in the stroma. The stromal protein phosphatase did not discriminate between dephosphorylation of phosphothreonine and phosphoserine residues in synthetic peptide substrates, providing further evidence that this enzyme is distinct from the protein phosphatase localized in thylakoid membranes. The exact physiological role of the stromal protein phosphatase has yet to be determined, but it may function in the dephosphorylation of LHC-II.     

Effects of synthetic peptides on thylakoid phosphoprotein phosphatase reactions

A synthetic peptide analogue of the phosphorylation site of LHC II, when phosphorylated by thylakoid membranes, served as a substrate for the thylakoid phosphoprotein phosphatase. The phosphopeptide became dephosphorylated at a low rate, comparable to that of the 9 kDa phosphoprotein. Phospho-LHC II itself became dephosphorylated much more rapidly, at a rate unaffected by endogenous phosphorylation of the peptide. Endogenous phosphorylation of the peptide was also without effect on other thylakoid protein phosphorylation and dephosphorylation reactions. In contrast, dephosphorylation of many thylakoid phosphoproteins was inhibited by addition of a pure, chemically-synthesised phosphopeptide analogue of phospho-LHC II. This result suggests that at least one thylakoid phosphoprotein phosphatase exhibits a broad substrate specificity. The results indicate that any one of a number of amino acid sequences can give a phosphoprotein configuration that is recognised by a single phosphatase.     

Chloroplast thylakoid protein phosphatase is a membrane surface-associated activity

Chloroplast thylakoid protein phosphatase activity was measured using ³²P-labeled histone as an exogenous substrate and an assay of the ³²Pi released involving formation of a phosphomolybdate complex and organic extraction. The activity was liberated from wheat (Triticum aestivum) thylakoids by washing the membranes in NaCl-containing solutions followed by centrifugation. The liberated phosphatase activity had a pH optimum of approximately 6.75, was inhibited by addition of 10 millimolar EDTA or EGTA, and was stimulated by addition of millimolar amounts of dithiothreitol, magnesium, manganese, or calcium ions. The rate of thylakoid protein dephosphorylation was decreased following liberation of a portion of the protein phosphatase activity and was increased by addition of salt-liberated phosphatase fraction. These results suggest that at least a portion of wheat thylakoid protein phosphatase is a peripheral, rather than an integral, membrane protein.     

Phosphoprotein phosphatase associated with rat liver plasma membrane. Properties of phosphorylase phosphatase and phosphohistone phosphatase

Plasma membrane isolated from rat liver contained activities of phosphoprotein phosphatase dephosphorylating [32P]phosphorylase a or [32P]phosphohistone. The properties of the membrane-bound phosphatase were examined using these exogenous substrates. The optimal reaction rate was at pH near neutrality. At concentrations as low as 0.1-1.0 mM, Mg2+ or Mn2+ slightly stimulated the activity for phosphorylase a or phosphohistone, respectively; at higher concentrations, they were inhibitory with both substrates. Co2+ was inhibitory with both substrates, while Ca2+ had no significant effect. The phosphatase activities were inhibited by ATP, ADP, or AMP; the extents of inhibition were in opposite order with the two substrates. Phosphorylase phosphatase activity was strongly inhibited by KF or Pi. Phosphorylase phosphatase activity could be completely solubilized by incubating the membrane with 0.5 M NaCl or trypsin, and this was associated with several-fold activation. While Vmax values were increased, Km values for phosphorylase a were not much affected by these treatments. Unlike the soluble phosphatase, freezing in the presence of mercaptoethanol or by precipitation with ethanol failed to activate or to solubilize the membrane-bound phosphatase. The molecular weights of the NaCl-and the trypsin-solubilized phosphatase were estimated on gel filtration to be about 42,000 and 32,000, respectively. The present results indicate that the phosphoprotein phosphatase associated with liver plasma membrane shares several properties in common with phosphatases from other sources reported, and that, like those in the soluble fraction, it may be bound to some inhibitory proteins.     

Purification and characterization of multiple S6 phosphatases from the rat parotid gland

S6 phosphatase activities, which dephosphorylate the phosphorylated S6 synthetic peptide, RRLSSLRASTSKSESSQK, were purified to near homogeneity from the membrane and cytosolic fractions of the rat parotid gland. Multiple S6 phosphatases were fractionated on Mono Q and gel filtration columns. In the cytosolic fraction, at least three forms of S6 phosphatase, termed peaks I, II, and III, were differentially resolved. The three forms had different sizes and protein compositions. The peak I enzyme, which had an approximately Mr of 68 kDa on gel filtration, appears to represent a dimeric form of the 39 kDa protein. This S6 phosphatase showed the high activity in the presence of EGTA and was completely inhibited by nanomolar concentrations of either okadaic acid or inhibitor 2. The peak II S6 phosphatase enzyme, with an Mr of 35 kDa, was activated by Mn²⁺. This form could be a proteolytic product of the catalytic subunit of type 1 phosphatase, due to its sensitivities to okadaic acid and inhibitor 2. The peak III enzyme, with an Mr of 55 kDa, is a Mn²⁺-dependent S6 phosphatase. This S6 phosphatase can be classified as a type 1 phosphatase, due to its sensitivity to okadaic acid, since the IC₅₀ of okadaic acid is 4 nM. However, the molecular mass of this S6 phosphatase differs from that of the type 1 catalytic subunit (37 kDa) and showed less sensitivity to inhibitor 2. On the other hand, the membrane fraction contained one form of the S6 phosphatases, termed peak V (Mr 34 and 28 kDa), which could be classified as a type 1 phosphatase. This S6 phosphatase activity was greatly stimulated by Mn²⁺.Abbreviations PP1-C catalytic subunit of type 1 protein phosphatase - SDS sodium dodecyl sulfate - Hepes 4-(2-hydroxyethyl)-1-piperazineethane sulfonic acid - PMSF phenylmethylsulfonyl fluoride - Mops 4-morpholine propanesulfonic acid - EDTA ethylenediaminetetraacetate - EGTA [ethylenbis (oxyethylenenitrilo)]-tetra acetic acid     

Phosphorylation and dephosphorylation of human platelet surface proteins by an ecto-protein kinase/phosphatase system.

We have characterized a novel ecto-protein kinase activity and a novel ecto-protein phosphatase activity on the membrane surface of human platelets. Washed intact platelets, when incubated with [gamma-32P]ATP in Tyrode's buffer, showed the phosphorylation of a membrane surface protein migrating with an apparent molecular mass of 42 kDa on 5-15% SDS polyacrylamide gradient gels. The 42 kDa protein could be further resolved on 15% SDS gels into two proteins of 39 kDa and 42 kDa. In this gel system, it was found that the 39 kDa protein became rapidly phosphorylated and dephosphorylated, whereas the 42 kDa protein was phosphorylated and dephosphorylated at a much slower rate. NaF inhibited the dephosphorylation of these proteins indicating the involvement of an ecto-protein phosphatase. The platelet membrane ecto-protein kinase responsible for the phosphorylation of both of these proteins was identified as a serine kinase and showed dependency on divalent cations Mg2+ or Mn2+ ions. Ca2+ ions potentiated the Mg(2+)-dependent ecto-protein kinase activity. The ecto-protein kinase rapidly phosphorylated histone and casein added exogenously to the extracellular medium of intact platelets. Following activation of platelets by alpha-thrombin, the incorporation of [32P]phosphate from exogenously added [gamma-32P]ATP by endogenous protein substrates was reduced by 90%, suggesting a role of the ecto-protein kinase system in the regulation of platelet function. The results presented here demonstrate that both protein kinase and protein phosphatase activities reside on the membrane surface of human platelets. These activities are capable of rapidly phosphorylating and dephosphorylating specific surface platelet membrane proteins which may play important roles in early events of platelet activation and secretion.     

Unique biochemical properties of the protein tyrosine phosphatase activity of PTEN—Demonstration of different active site structural requirements for phosphopeptide and phospholipid phosphatase activities of PTEN

Missense PTEN mutations of the active site residues Asp-92, Cys-124 and Gly-129 contribute to Cowden syndrome. How their mutations affect phospholipid phosphatase activity and tumor suppressor function of PTEN has been defined. In this study, we investigated how their mutations affect the kinetics and catalytic mechanism of PTEN phosphoprotein phosphatase activity. Our data suggest that PTEN catalysis of phosphoprotein dephosphorylation follows a two-step mechanism with Cys-124 transiently phosphorylated to form the phosphoenzyme intermediate. In spite of this, we were unable to trap the genuine phosphoenzyme intermediate; instead, we unexpectedly discovered a novel phosphotransfer reaction in which the phosphate group is transferred from a tyrosyl phosphopeptide to PTEN to form a unique phosphorylated protein. Even though the finding is novel, the phosphotransfer reaction is likely an in vitro non-enzymatic reaction. Kinetic analysis revealed that mutation of Asp-92 has negligible impacts on phosphopeptide phosphatase activity of PTEN, suggesting that Asp-92 does not participate in the phosphopeptide dephosphorylation reaction. The results also imply that allosteric regulators facilitating the recruitment of Asp-92 to participate in catalysis will increase the activity of PTEN in dephosphorylating phosphoprotein and phosphopeptide substrates. Furthermore, kinetic analysis revealed that the G129E mutation has different effects on phospholipid and phosphoprotein phosphatase activities. Taken together, the data show that while the two phosphatase activities of PTEN follow a similar catalytic mechanism, they have notable differences in the requirements of the active site structure.     

Phosphatase activity in rat adipocytes: effects of insulin and insulin resistance

Insulin regulates the activity of both protein kinases and phosphatases. Little is known concerning the subcellular effects of insulin on phosphatase activity and how it is affected by insulin resistance. The purpose of this study was to determine insulin-stimulated subcellular changes in phosphatase activity and how they are affected by insulin resistance. We used an in vitro fatty acid (palmitate) induced insulin resistance model, differential centrifugation to fractionate rat adipocytes, and a malachite green phosphatase assay using peptide substrates to measure enzyme activity. Overall, insulin alone had no effect on adipocyte tyrosine phosphatase activity; however, subcellularly, insulin increased plasma membrane adipocyte tyrosine phosphatase activity 78 +/- 26% (n = 4, P < 0.007), and decreased high-density microsome adipocyte tyrosine phosphatase activity 42 +/- 13% (n = 4, P < 0.005). Although insulin resistance induced specific changes in basal tyrosine phosphatase activity, insulin-stimulated changes were not significantly altered by insulin resistance. Insulin-stimulated overall serine/threonine phosphatase activity by 16 +/- 5% (n = 4, P < 0.005), which was blocked in insulin resistance. Subcellularly, insulin increased plasma membrane and crude nuclear fraction serine/threonine phosphatase activities by 59 +/- 19% (n = 4, P < 0. 005) and 21 +/- 7% (n = 4, P < 0.007), respectively. This increase in plasma membrane fractions was inhibited 23 +/- 7% (n = 4, P < 0. 05) by palmitate. Furthermore, insulin increased cytosolic protein phosphatase-1 (PP-1) activity 160 +/- 50% (n = 3, P < 0.015), and palmitate did not significantly reduce this activity. However, palmitate did reduce insulin-treated low-density microsome protein phosphatase-1 activity by 28 +/- 6% (n = 3, P < 0.04). Insulin completely inhibited protein phosphatase-2A activity in the cytosol and increased crude nuclear fraction protein phosphatase-2A activity 70 +/- 29% (n = 3, P < 0.038). Thus, the major effects of insulin on phosphatase activity in adipocytes are to increase plasma membrane tyrosine and serine/threonine phosphatase, crude nuclear fraction protein phosphatase-2A, and cytosolic protein phosphatase-1 activities, while inhibiting cytosolic protein phosphatase-2A. Insulin resistance was characterized by reduced insulin-stimulated serine/threonine phosphatase activity in the plasma membrane and low-density microsomes. Specific changes in phosphatase activity may be related to the development of insulin resistance.     

Identification of a Role for an Azide-Sensitive Factor in the Thylakoid Transport of the 17-Kilodalton Subunit of the Photosynthetic Oxygen-Evolving Complex

We have examined the transport of the precursor of the 17-kD subunit of the photosynthetic O₂-evolving complex (OE17) in intact chloroplasts in the presence of inhibitors that block two protein-translocation pathways in the thylakoid membrane. This precursor uses the transmembrane pH gradient-dependent pathway into the thylakoid lumen, and its transport across the thylakoid membrane is thought to be independent of ATP and the chloroplast SecA homolog, cpSecA. We unexpectedly found that azide, widely considered to be an inhibitor of cpSecA, had a profound effect on the targeting of the photosynthetic OE17 to the thylakoid lumen. By itself, azide caused a significant fraction of mature OE17 to accumulate in the stroma of intact chloroplasts. When added in conjunction with the protonophore nigericin, azide caused the maturation of a fraction of the stromal intermediate form of OE17, and this mature protein was found only in the stroma. Our data suggest that OE17 may use the sec-dependent pathway, especially when the transmembrane pH gradient-dependent pathway is inhibited. Under certain conditions, OE17 may be inserted across the thylakoid membrane far enough to allow removal of the transit peptide, but then may slip back out of the translocation machinery into the stromal compartment.     

Phosphoprotein phosphatase activity of rat liver nuclear membrane.

Nuclear membranes from rat liver contain a phosphoprotein phosphatase activity capable of dephosphorylating endogenous nuclear membrane phosphoproteins. This activity was also expressed towards the ³²P-labeled exogenous phosphoprotein substrates phosvitin and lysine-rich histone. Differential effects of altered ionic strength, EDTA, pyrophosphate, and 2-mercaptoethanol on the phosphatase activity towards the two exogenous substrates suggest the presence of multiple phosphatases in the nuclear membrane. ATP, ADP, and sodium fluoride inhibited activity towards both exogenous substrates, while cyclic AMP or cyclic GMP at 10^?6M had no apparent effect.     

Degradation of mistargeted OEE33 in the chloroplast stroma

OEE33, a component of the oxygen-evolving enzyme in chloroplasts, normally resides in the thylakoid lumen. In an attempt to study the fate of mistargeted proteins in chloroplasts, we substituted the bipartite transit peptide of OEE33 with that of CAB7, an integral thylakoid-membrane protein. As a result, when imported into isolated chloroplasts, the chimeric protein was targeted to the stroma instead of the thylakoid lumen. Whereas the wild-type OEE33 was totally stable for at least 2 h, the chimeric protein was rapidly degraded, with a half-life of 60 min. Degradation of the chimeric protein was stimulated by ATP supplementation. Degradation could also be observed in lysed chloroplasts, in an ATP-stimulated manner. When lysates were fractionated, the proteolytic activity was found to be associated mainly with the stromal fraction. This activity was very effectively inhibited by all tested inhibitors of serine proteases. Western blot analysis demonstrated that the stromal fraction active in degrading the chimeric OEE33 contains ClpC and ClpP, homologues of the regulatory and proteolytic subunits, respectively, of the bacterial, ATP-dependent, serine-type Clp protease.     

Monoclonal antibodies to the light-harvesting chlorophyll a/b protein complex of photosystem II

A collection of 17 monoclonal antibodies elicited against the light-harvesting chlorophyll a/b protein complex which serves photosystem II (LHC-II) of Pisum sativum shows six classes of binding specificity. Antibodies of two of the classes recognize a single polypeptide (the 28- or the 26- kD polypeptides), thereby suggesting that the two proteins are not derived from a common precursor. Other classes of antibodies cross-react with several polypeptides of LHC-II or with polypeptides of both LHC-II and the light-harvesting chlorophyll a/b polypeptides of photosystem I (LHC-I), indicating that there are structural similarities among the polypeptides of LHC-II and LHC-I. The evidence for protein processing by which the 26-, 25.5-, and 24.5-kD polypeptides are derived from a common precursor polypeptide is discussed. Binding studies using antibodies specific for individual LHC-II polypeptides were used to quantify the number of antigenic polypeptides in the thylakoid membrane. 27 copies of the 26-kD polypeptide and two copies of the 28-kD polypeptide were found per 400 chlorophylls. In the chlorina f2 mutant of barley, and in intermittent light-treated barley seedlings, the amount of the 26-kD polypeptide in the thylakoid membranes was greatly reduced, while the amount of 28-kD polypeptide was apparently not affected. We propose that stable insertion and assembly of the 28-kD polypeptide, unlike the 26-kD polypeptide, is not regulated by the presence of chlorophyll b.     

Chloroplast phosphoproteins. Evidence for a thylakoid-bound phosphoprotein phosphatase

1. Isolated intact pea (Pisum sativum) chloroplasts incorporate [32P]orthophosphate into several thylakoid polypeptides in the light. Transfer of the labelled chloroplasts to darkness results in rapid dephosphorylation of the polypeptides. The most rapidly dephosphorylated phosphoproteins are the 26000-Mr doublet derived from the light-harvesting chlorophyll a/b binding complex. 2. Incubation of isolated 32P-labelled thylakoids in buffer in the absence of stromal components also results in rapid protein dephosphorylation. Again, the most rapidly dephosphorylated phosphoproteins are the 26000-Mr light-harvesting doublet. Dephosphorylation of all thylakoid phosphoproteins is accelerated by addition of up to 10 mM MgCl2. 3. The enzyme responsible for dephosphorylation is a phosphatase rather than a phosphotransferase or the thylakoid protein kinase acting in reverse. The enzyme is specifically and totally inhibited by NaF and does not require phosphoryl group acceptors such as ADP. Unlike the protein kinase, the phosphatase is indifferent to light and the electron transport inhibitor 3(3,4-dichlorophenyl)-1,1-dimethylurea. 4. The phosphorylated regions of the thylakoid phosphoproteins protrude from the outer surface of the membrane and are removed by trypsin treatment.     

Molecular and Physiological Analysis of a Thylakoid K+ Channel Protein

Transport studies identified a K+ channel protein in preparations of purified spinach (Spinacea oleracea) thylakoid membrane. This protein was solubilized from native membranes and reconstituted into artificial proteoliposomes with maintenance of functional integrity. A 33-kD thylakoid polypeptide was identified as a putative component of this thylakoid protein. This identification was made using an antibody raised against a synthetic peptide representing a highly conserved region of K+ channel proteins. K+ channel activity co-migrated with the immunoreactive 33-kD polypeptide when solubilized thylakoid membrane protein was fractionated on a Suc density gradient. The antibody was used to immunoprecipitate the 33-kD polypeptide. Physiological function of this thylakoid membrane protein was elucidated by measuring photosynthetic electron transport of thylakoid preparations in the presence and absence of a K+ channel blocker. Results indicated that K+ efflux from the thylakoid lumen through this channel protein is required for the optimization of photosynthetic capacity. The effect this protein has on photosynthetic capacity is likely due to the requirement for K+ efflux from the thylakoid lumen to charge-balance light-induced proton pumping across this membrane.     

A cyclophilin-regulated PP2A-like protein phosphatase in thylakoid membranes of plant chloroplasts.

Dephosphorylation of central photosynthetic proteins regulates their turnover in plant thylakoid membranes. A membrane protein phosphatase from spinach thylakoids was purified 13000-fold using detergent-engaged FPLC. The purified enzyme exhibited characteristics typical of eukaryotic Ser/Thr phosphatases of the PP2A family in that it was inhibited by okadaic acid (IC(50) = 0.4 nM) and tautomycin (IC(50) = 25 nM), irreversibly bound to microcystin-agarose, and recognized by a polyclonal antibody raised against a recombinant catalytic subunit of human PP2A. Furthermore, the anti-PP2A antibody inhibited protein dephosphorylation in isolated thylakoids. The phosphatase copurified with TLP40, a cyclophilin-like peptidyl-prolyl isomerase located in the thylakoid lumen. TLP40 could be released from the phosphatase immobilized on microcystin-agarose by high-salt treatment. Binding of cyclosporin A (CsA) to TLP40 led to thylakoid phosphatase activation, while cyclophilin substrates, prolyl-containing oligopeptides, inhibited protein dephosphorylation. This dephosphorylation could be modulated by CsA or oligopeptides only after the thylakoids had been ruptured to expose the lumenal membrane surface where the TLP40 is located. Regulation of the PP2A-like phosphatase at the outer thylakoid surface is likely to operate via reversible binding of TLP40 to the inner membrane surface. This is a first example of transmembrane regulation in which the activity of phosphatase is altered by the binding of a cyclophilin to a site other than the active one. We propose that signaling from TLP40 to the protein phosphatase coordinates dephosphorylation and protein folding, two processes required for protein turnover during the repair of photoinhibited photosystem II reaction centers.     

Effect of vanadate, molybdate, and azide on membrane-associated ATPase and soluble phosphatase activities of corn roots

The effects of vanadate, molybdate, and azide on ATP phosphohydrolase (ATPase) and acid phosphatase activities of plasma membrane, mitochondrial, and soluble supernatant fractions from corn (Zea mays L. WF9 × MO17) roots were investigated. Azide (0.1-10 millimolar) was a selective inhibitor of pH 9.0-ATPase activity of the mitochondrial fraction, while molybdate (0.01-1.0 millimolar) was a relatively selective inhibitor of acid phosphatase activity in the supernatant fraction. The pH 6.4-ATPase activity of the plasma membrane fraction was inhibited by vanadate (10-500 micromolar), but vanadate, at similar concentrations, also inhibited acid phosphatase activity. This result was confirmed for oat (Avena sativa L.) root and coleoptile tissues. While vanadate does not appear to be a selective inhibitor, it can be used in combination with molybdate and azide to distinguish the plasma membrane ATPase from mitochondrial ATPase or supernatant acid phosphatase.

Vanadate appeared to be a noncompetitive inhibitor of the plasma membrane ATPase, and its effectiveness was increased by K⁺. K⁺-stimulated ATPase activity was inhibited by 50% at about 21 micromolar vanadate. The rate of K⁺ transport in excised corn root segments was inhibited by 66% by 500 micromolar vanadate.

     

Crystallisation, structure and function of plant light-harvesting Complex II

The chlorophyll a/b light-harvesting complex of photosystem II (LHC-II) collects most of the solar energy in the biosphere. LHC-II is the prototype of a highly conserved family of membrane proteins that fuels plant photosynthesis in the conversion of excitation energy into biologically useful chemical energy. In addition, LHC-II plays an important role in the organisation of the thylakoid membrane, the structure of the photosynthetic apparatus, the regulation of energy flow between the two photosystems, and in the controlled dissipation of excess excitation energy under light stress. Our current understanding of the sophisticated mechanisms behind each of these processes has profited greatly from the progress made over the past two decades in determining the structure of the complex. This review presents the developments and breakthroughs that ultimately lead to the high-resolution structure of LHC-II. Based on an alignment of the remarkably well engineered and highly conserved LHC polypeptide, we propose several key features of the LHC-II structure that are likely to be present in all members of the LHC family. Finally, some recently proposed mechanisms of energy-dependent non-photochemical quenching (NPQ) are examined from a structural perspective.     

Biochemical Properties and Inhibition Kinetics of Phosphatase from Wheat Thylakoid Membranes

A phosphetase that hydrolyses phosphate monoesters has been Isolated from wheat thylakold membranes. Biochemical properties and inhibition kinetics of the phosphatase were Investigated using several Ions, organlc solvents, and Inhlbltors. Wheat （Trltlcum aestivum L. cv. PH82-2-2） thylakold membrane phosphatase activity was activated by Mg^2＋, Ca^2＋, and Fe^2＋ and was inhibited by Mn^2＋ and Cu^2＋. For example, enzyme activity was acUvated 34.81% by 2 mmol/l. Mg^2＋, but was Inhibited 22.3% and 8.5% by 2 and 1 mmol/L Cu^2＋, respectively. Methanol, ethanol and glycol were all able to activate enzyme activity. Enzyme activity was activated 58.5%, 48.2%, and 8.7% by 40% ethanol, methanol and glycol, respectively. From these results, It can be seen that the degree of actlvetlon of the phosphetase was greatest for ethanol and the type of acUvatlon was uncompetltlve. Moreover, the activity of the thylakold membrane phosphetase was Inhibited by molybdate, vanadete, phosphate, and fluoride and the type of Inhibition produced by these elements was uncompetltlve, non-competitive, competltlve and mixed, respectively.     

PTPH1 is a predominant protein-tyrosine phosphatase capable of interacting with and dephosphorylating the T cell receptor zeta subunit

Protein-tyrosine phosphatases (PTPases) play key roles in regulating tyrosine phosphorylation levels in cells, yet the identity of their substrates remains limited. We report here on the identification of PTPases capable of dephosphorylating the phosphorylated immune tyrosine-based activation motifs present in the T cell receptor zeta subunit. To characterize these PTPases, we purified enzyme activities directed against the phosphorylated T cell receptor zeta subunit by a combination of anion and cation chromatography procedures. A novel ELISA-based PTPase assay was developed to rapidly screen protein fractions for enzyme activity following the various chromatography steps. We present data that SHP-1 and PTPH1 are present in highly enriched protein fractions that exhibit PTPase activities toward a tyrosine-phosphorylated TCR zeta substrate (specific activity ranging from 0.23 to 40 pmol/min/microg). We also used a protein-tyrosine phosphatase substrate-trapping library comprising the catalytic domains of 47 distinct protein-tyrosine phosphatases, representing almost all the tyrosine phosphatases identified in the human genome. PTPH1 was the predominant phosphatase capable of complexing phospho-zeta. Subsequent transfection assays indicated that SHP-1 and PTPH1 are the two principal PTPases capable of regulating the phosphorylation state of the TCR zeta ITAMs, with PTPH1 directly dephosphorylating zeta. This is the first reported demonstration that PTPH1 is a candidate PTPase capable of interacting with and dephosphorylating TCR zeta.