Assay of protein tyrosine phosphatases by using matrix-assisted laser desorption ionization time-of-flight mass spectrometry

A nonradioactive assay for protein tyrosine phosphatases (PTPs), employing a tyrosine-phosphorylated peptide as a substrate, has been developed and applied to analyze purified enzymes, cell extracts, and immunoprecipitates. The reaction was followed by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) in a linear and positive ion mode with delayed extraction. MALDI-TOF MS detects a loss of peptide mass by 80 Da as a result of dephosphorylation and, more importantly, it yields phospho-peptide to dephosphorylated product peak intensity ratios proportional to their concentration ratios. A strong bias of the MALDI-TOF MS toward detection of the non-phospho-peptide allows accurate detection of small fractions of dephosphorylation. The method is highly sensitive and reproducible. It can be applied to general assays of protein phosphatases with various phospho-peptides as substrates.     

Substrate specificity of Ca(2+)/calmodulin-dependent protein kinase phosphatase: kinetic studies using synthetic phosphopeptides as model substrates

Ca(2+)/calmodulin-dependent protein kinase phosphatase (CaMKPase) dephosphorylates and regulates multifunctional Ca(2+)/calmodulin-dependent protein kinases. In order to elucidate the mechanism of substrate recognition by CaMKPase, we chemically synthesized a variety of phosphopeptide analogs and carried out kinetic analysis using them as CaMKPase substrates. This is the first report using systematically synthesized phosphopeptides as substrates for kinetic studies on substrate specificities of protein Ser/Thr phosphatases. CaMKPase was shown to be a protein Ser/Thr phosphatase having a strong preference for a phospho-Thr residue. A Pro residue adjacent to the dephosphorylation site on the C-terminal side and acidic clusters around the dephosphorylation site had detrimental effects on dephosphorylation by CaMKPase. Deletion analysis of a model substrate peptide revealed that the minimal length of the substrate peptide was only 2 to 3 amino acid residues including the dephosphorylation site. The residues on the C-terminal side of the dephosphorylation site were not essential for dephosphorylation, whereas the residue adjacent to the dephosphorylation site on the N-terminal side was essential. Ala-scanning analysis suggested that CaMKPase did not recognize a specific motif around the dephosphorylation site. Myosin light chain phosphorylated by protein kinase C and Erk2 phosphorylated by MEK1 were poor substrates for CaMKPase, while a synthetic phosphopeptide corresponding to the sequence around the phosphorylation site of the former was not dephosphorylated by CaMKPase but that of the latter was fairly good substrate. These data suggest that substrate specificity of CaMKPase is determined by higher-order structure of the substrate protein rather than by the primary structure around its dephosphorylation site. Use of phosphopeptide substrates also revealed that poly-L-lysine, an activator for CaMKPase, activated the enzyme mainly through increase in the V(max) values.     

Phosphotyrosine Substrate Sequence Motifs for Dual Specificity Phosphatases

Protein tyrosine phosphatases dephosphorylate tyrosine residues of proteins, whereas, dual specificity phosphatases (DUSPs) are a subgroup of protein tyrosine phosphatases that dephosphorylate not only Tyr(P) residue, but also the Ser(P) and Thr(P) residues of proteins. The DUSPs are linked to the regulation of many cellular functions and signaling pathways. Though many cellular targets of DUSPs are known, the relationship between catalytic activity and substrate specificity is poorly defined. We investigated the interactions of peptide substrates with select DUSPs of four types: MAP kinases (DUSP1 and DUSP7), atypical (DUSP3, DUSP14, DUSP22 and DUSP27), viral (variola VH1), and Cdc25 (A-C). Phosphatase recognition sites were experimentally determined by measuring dephosphorylation of 6,218 microarrayed Tyr(P) peptides representing confirmed and theoretical phosphorylation motifs from the cellular proteome. A broad continuum of dephosphorylation was observed across the microarrayed peptide substrates for all phosphatases, suggesting a complex relationship between substrate sequence recognition and optimal activity. Further analysis of peptide dephosphorylation by hierarchical clustering indicated that DUSPs could be organized by substrate sequence motifs, and peptide-specificities by phylogenetic relationships among the catalytic domains. The most highly dephosphorylated peptides represented proteins from 29 cell-signaling pathways, greatly expanding the list of potential targets of DUSPs. These newly identified DUSP substrates will be important for examining structure-activity relationships with physiologically relevant targets.     

Tyrosine Hydroxylase Dephosphorylation by Protein Phosphatase 2A in Bovine Adrenal Chromaffin Cells

This study was undertaken to characterise the protein phosphatases in bovine adrenal chromaffin cells acting on tyrosine hydroxylase. Cells were pre-labelled with ³²P_i and permeabilized with digitonin. The extent of dephosphorylation of Ser-8, Ser-19, Ser-31 and Ser-40 on tyrosine hydroxylase was found to be 30%, 38%, 37% and 71% respectively over 5 min. For Ser-19, Ser-31 and Ser-40 the dephosphorylation was entirely due to protein phosphatase 2A, as the dephosphorylation could be completely blocked by microcystin, but not by the protein phosphatase 1 inhibitory peptide. Permeabilization did not change the distribution of protein phosphatase 2A or tyrosine hydroxylase, or the activity of PP2A, from that occurring in intact cells. The dephosphorylation of Ser-8 was not altered by any inhibitor, suggesting the involvement of other protein phosphatases. The method developed here can be used to determine the protein phosphatases acting on substrates in conditions closely approximating those in situ, including the endogenous state of substrate phosphorylation and phosphatase location.     

Molecular basis for substrate specificity of protein kinases and phosphatases

Regulation of various metabolic processes occurs by the phosphorylation/dephosphorylation of enzymes. Both the protein kinases that catalyze the phosphorylations and the protein phosphatases that catalyze the dephosphorylations display relatively broad specificity, reacting with a number of distinct sites in target enzymes. In this way changes in the activity of a particular kinase or phosphatase can cause coordinated and pleiotropic responses. However, the kinases and phosphatases do not exhibit a one-to-one correspondence in their reactions. Residues at different positions may be phosphorylated by a single kinase, yet dephosphorylated by different individual phosphatases. Conversely, sites which are substrates for different individual kinases may be dephosphorylated by a single phosphatase. In exploring the molecular basis for these differences this article shows that whereas kinases react with specific primary structures that often times appear as beta bends, the phosphatases recognize higher order structure, less strictly ruled by amino acid sequence surrounding the phosphorylated site. The differences, seen in the ability of these enzymes to utilize synthetic peptide substrates, might be rationalized in terms of function. Kinases need protruding segments of structure that can be enwrapped to exclude water, thereby minimizing ATP hydrolysis and enhancing phosphotransferase activity. On the other hand phosphatases are hydrolytic enzymes that may operate especially well on protein interfaces. Hydrolytic action often measured with p-nitrophenylphosphate is not necessarily indicative of a protein phosphatase and consideration of the mechanism reveals why this substrate can be misleading.(ABSTRACT TRUNCATED AT 250 WORDS)     

Prediction of substrate sites for protein phosphatases 1B,SHP-1, and SHP-2 based on sequence features

Tyrosine phosphorylation plays crucial roles in numerous physiological processes. The level of phosphorylation state depends on the combined action of protein tyrosine kinases and protein tyrosine phosphatases. Detection of possible phosphorylation and dephosphorylation sites can provide useful information to the functional studies of relevant proteins. Several studies have focused on the identification of protein tyrosine kinase substrates. However, compared with protein tyrosine kinases, the prediction of protein tyrosine phosphatase substrates involved in the balance of protein phosphorylation level falls behind. This paper described a method that utilized the k-nearest neighbor algorithm to identity the substrate sites of three protein tyrosine phosphatases based on the sequence features of manually collected dephosphorylation sites. In the performance evaluation, both sensitivities and specificities could reach above 75 % for all three protein tyrosine phosphatases. Finally, the method was applied on a set of known tyrosine phosphorylation sites to search for candidate substrates.     

A homogeneous, nonradioactive high-throughput fluorogenic protein phosphatase assay

Protein phosphatases are critical components in cellular regulation; they do not only act as antioncogenes by antagonizing protein kinases, but they also play a positive regulatory role in a variety of cellular processes that require dephosphorylation. Thus, assessing the function of these enzymes necessitates the need for a robust, sensitive assay that accurately measures their activities. The authors present a novel, homogeneous, and nonradioactive assay to measure the enzyme activity of low concentrations of several protein phosphatases (phosphoserine/phosphothreonine phosphatases and phosphotyrosine phosphatases). The assay is based on the use of fluorogenic peptide substrates (rhodamine 110, bis-phosphopeptide amide) that do not fluoresce in their conjugated form, which is resistant to cleavage by aminopeptidases. However, upon dephosphorylation by the phosphatase of interest, the peptides become cleavable by the protease and release the highly fluorescent-free rhodamine 110. The assay is rapid, can be completed in less than 2 h, and can be carried out in multiwell plate formats such as 96-, 384-, and 1536-well plates. The assay has an excellent dynamic range, high signal-to-noise ratio, and a Z' of more than 0.8, and it is easily adapted to a robotic system for drug discovery programs targeting protein phosphatases.     

Assay of phosphotyrosyl protein phosphatase using synthetic peptide 1142-1153 of the insulin receptor

Synthetic peptide 1142-1153 of the insulin receptor was phosphorylated on tyrosine by the insulin receptor and found to be a potent substrate for dephosphorylation by rat liver particulate and soluble phosphotyrosyl protein phosphatases. Apparent Km values were approximately 5 microM. Vm values (nmol phosphate removed/min per mg protein) were 0.62 (particulate) and 0.2 (soluble). This corresponds to 80% of total activity being membrane-associated, indicating that membrane-bound phosphatases are important receptor phosphatases. The phosphatase activities were distinct from acid and alkaline phosphatase. In conclusion peptide 1142-1153 provides a useful tool for the further study and characterization of phosphotyrosyl protein phosphatases.     

Synthetic peptides as model substrates for the study of the specificity of the polycation-stimulated protein phosphatases

The substrate specificity of the different forms of the polycation-stimulated (PCS, type 2A) protein phosphatases and of the active catalytic subunit of the ATP, Mg-dependent (type 1) phosphatase (AMDC) was investigated, using synthetic peptides phosphorylated by either cyclic-AMP-dependent protein kinase or by casein kinase-2. The PCS phosphatases are very efficient toward the Thr(P) peptides RRAT(P)VA and RRREEET(P)EEE when compared with the Ser(P) analogues RRAS(P)VA and RRREEES(P)EEEAA. Despite their distinct sequence, both Thr(P) peptides are excellent substrates for the PCSM and PCSH1 phosphatases, being dephosphorylated faster than phosphorylase a. The slow dephosphorylation of RRAS(P)VA by the PCS phosphatases could be increased substantially by the insertion of N-terminal (Arg) basic residues. In contrast with the latter, the AMDC phosphatase shows very poor activity toward all the phosphopeptides tested, without preference for either Ser(P) or Thr(P) peptides. However, N-terminal basic residues also favor the dephosphorylation of otherwise almost inert substrates by the AMDC phosphatase. Hence, while the dephosphorylation of Thr(P) substrates by the PCS phosphatases is highly favored by the nature of the phosphorylated amino acid, phosphatase activity toward Ser(P)-containing peptides may require specific determinants in the primary structure of the phosphorylation site.     

Identification of new substrates of the protein-tyrosine phosphatase PTP1B by Bayesian integration of proteome evidence

There is growing evidence that tyrosine phosphatases display an intrinsic enzymatic preference for the sequence context flanking the target phosphotyrosines. On the other hand, substrate selection in vivo is decisively guided by the enzyme-substrate connectivity in the protein interaction network. We describe here a system wide strategy to infer physiological substrates of protein-tyrosine phosphatases. Here we integrate, by a Bayesian model, proteome wide evidence about in vitro substrate preference, as determined by a novel high-density peptide chip technology, and "closeness" in the protein interaction network. This allows to rank candidate substrates of the human PTP1B phosphatase. Ultimately a variety of in vitro and in vivo approaches were used to verify the prediction that the tyrosine phosphorylation levels of five high-ranking substrates, PLC-γ1, Gab1, SHP2, EGFR, and SHP1, are indeed specifically modulated by PTP1B. In addition, we demonstrate that the PTP1B-mediated dephosphorylation of Gab1 negatively affects its EGF-induced association with the phosphatase SHP2. The dissociation of this signaling complex is accompanied by a decrease of ERK MAP kinase phosphorylation and activation.     

An investigation of the substrate specificity of protein phosphatase 2C using synthetic peptide substrates; comparison with protein phosphatase 2A

The synthetic phosphopeptide RRATpVA was found to be the most effective substrate for protein phosphatase 2C (PP2C) so far identified. Replacement of phosphothreonine by phosphoserine decreased activity over 20-fold and a striking preference for phosphothreonine was also observed with two other substrates (RRSTpTpVA and casein) that were phosphorylated on both serine and threonine. Replacement of the C-terminal valine in RRATpVA by proline abolished dephosphorylation, while exchanging the N-terminal alanine by proline had no effect. The preference for phosphothreonine and the effect of proline are similar to protein phosphatase 2A (PP2A). However, the peptide RRREEETpEEEAA, an excellent substrate for PP2A, was not dephosphorylated by PP2C, and substitution of the C-terminal valine in RRATpVA by glutamic acid reduced the rate of dephosphorylation by PP2C over 10-fold, without affecting dephosphorylation by PP2A. Addition of two extra N-terminal arginine residues to RRASpVA increased PP2A catalysed dephosphorylation 4- to 5-fold, without altering dephosphorylation by PP2C. These results represent the first study of the specificity of PP2C using synthetic peptides, and strengthen the view that this approach may lead to the development of more effective and specific substrates for the serine/threonine-specific protein phosphatases.     

Okadaic Acid-Induced Inhibition of B-50 Dephosphorylation by Presynaptic Membrane-Associated Protein Phosphatases

The neuronal tissue-specific protein kinase C (PKC) substrate B-50 can be dephosphorylated by endogenous protein phosphatases (PPs) in synaptic plasma membranes (SPMs). The present study characterizes membrane-associated B-50 phosphatase activity by using okadaic acid (OA) and purified 32P-labeled substrates. At a low concentration of [gamma-32P]ATP, PKC-mediated [32P]phosphate incorporation into B-50 in SPMs reached a maximal value at 30 s, followed by dephosphorylation. OA, added 30 s after the initiation of phosphorylation, partially prevented the dephosphorylation of B-50 at 2 nM, a dose that inhibits PP-2A. At the higher concentration of 1 microM, a dose of OA that inhibits PP-1 as well as PP-2A, a nearly complete blockade of B-50 dephosphorylation was seen. Heat-stable PP inhibitor-2 (I-2) also inhibited dephosphorylation of B-50. The effects of OA and I-2 on B-50 phosphatase activity were additive. Endogenous PP-1- and PP-2A-like activities in SPMs were also demonstrated by their capabilities of dephosphorylating [32P]phosphorylase a and [32P]casein. With these exogenous substrates, sensitivities of the membrane-bound phosphatases to OA and I-2 were found to be similar to those of purified forms of these enzymes. These results indicate that PP-1- and PP-2A-like enzymes are the major B-50 phosphatases in SPMs.     

A kinetic approach for the study of protein phosphatase-catalyzed regulation of protein kinase activity

The activities of many protein kinases are regulated by phosphorylation. The phosphorylated protein kinases thus represent an important class of substrates for protein phosphatases. However, our ability to study the phosphatase-catalyzed substrate dephosphorylation has been limited in many cases by the difficulty in preparing sufficient amount of stoichiometrically phosphorylated kinases. We have applied the kinetic theory of substrate reaction during irreversible modification of enzyme activity to the study of phosphatase-catalyzed regulation of kinase activity. As an example, we measured the effect of the hematopoietic protein-tyrosine phosphatase (HePTP) on the reaction catalyzed by the fully activated, bisphosphorylated extracellular signal-regulated protein kinase 2 (ERK2/pTpY). Because only a catalytic amount of ERK2/pTpY is required, this method alleviates the need for large quantities of phospho-ERK2. Kinetic analysis of the ERK2/pTpY-catalyzed substrate reaction in the presence of HePTP leads to the determination of the rate constants for the HePTP-catalyzed dephosphorylation of free ERK2/pTpY and ERK2/pTpY*substrate(s) complexes. The data indicate that ERK2/pTpY is a highly efficient substrate for HePTP (k(cat)/K(m) = 3.05 x 10(6) M(-1) s(-1)). The data also show that binding of ATP to ERK2/pTpY has no effect on ERK2/pTpY dephosphorylation by HePTP. In contrast, binding of an Elk-1 peptide substrate to ERK2/pTpY completely blocks the HePTP action. This result indicates that phosphorylation of Tyr185 is important for ERK2 substrate recognition and that binding of the Elk-1 peptide substrate to ERK2/pTpY blocks the accessibility of pTyr185 to HePTP for dephosphorylation. Collectively, the results establish that the kinetic theory of irreversible enzyme modification can be applied to study the phosphatase catalyzed regulation of kinase activity.     

A Nonradioactive Fluorescent Gel-Shift Assay for the Analysis of Protein Phosphatase and Kinase Activities toward Protein-Specific Peptide Substrates

Synthetic peptides are important tools with which to study the activities of protein kinases and phosphatases toward specific substrate sequences which are present within selected regions of a protein. Most existing assays for the phosphorylation or dephosphorylation of such peptides utilize ³²P and either affinity chromatography or HPLC separation and require extensive characterization and validation. Here, we describe a method for monitoring the phosphorylation or dephosphorylation of almost any peptide of interest which does not require the use of radioactivity, making its reagents stable for a prolonged period, and which can be performed in any standard laboratory. For this, after performance of kinase or phosphatase reactions with the peptide of interest, products are derivatized with fluorescamine and are separated according to charge by agarose gel electrophoresis. Phosphorylated and nonphosphorylated peptides are readily separated and can be both identified and quantified by uv detection. The lower limit for detection of peptide in the agarose gel was 0.02 nmol using the gel-shift kinase assay with cAMP-dependent kinase and Kemptide as substrate. This had sensitivity and reproducibility similar to those of a standard assay using [γ-³²P]ATP with this substrate. Dephosphorylation of a synthetic phosphopeptide corresponding to a segment of the cholecystokinin receptor was tested in an analogous assay with known amounts of protein phosphatase 2A. Phosphopeptide and dephosphopeptide were easily detected and quantified with as little as 0.03 mU/mI protein phosphatase 2A activity. Therefore, with this assay, most synthetic peptides and phosphopeptides can be used as substrates without further modification. This will be of particular interest for monitoring the purification of highly specific protein kinase and phosphatase activities.     

Mutants of phosphorylase a altered in recognition by protein phosphatase-1

To develop our knowledge of specificity determinants for protein phosphatase-1, mutants of phosphorylase b have been converted to phosphorylase a and examined for their efficacy as substrates for protein phosphatase-1. Mutants focused on the N-terminal primary sequence surrounding the phosphoserine (R16A, R16E, and I13G) and at a site that interacts with the phosphoserine in phosphorylase a, (R69K and R69E). The success achieved studying protein kinase substrate specificity with peptide substrates has not extended to protein phosphatases. Protein phosphatases are believed to recognize higher order structure in substrates in addition to the primary sequence surrounding the phosphoserine or threonine. Peptide studies with protein phosphatase-1 have revealed a preference for basic residues N-terminal to the phosphoserine. Arginine 16 in phosphorylase a may be a positive determinant. In this work, protein phosphatase-1 preferred the positive charge on arginine 16. R16A exhibited a similar K(m) but reduced V(max), and R16E had an increased K(m) and a decreased V(max) when compared to phosphorylase. I13G had a similar K(m) but an increased V(max). The R69 mutants were also dephosphorylated preferentially over phosphorylase a. The K(m) for R69K was unchanged but had a higher V(max). R69E exhibited the most changes, with a 4-fold increase in K(m) and a 10-fold increase in V(max). These results suggest that proper presentation of the phosphoserine can greatly affect the rate of dephosphorylation.     

Cdc14 phosphatases preferentially dephosphorylate a subset of cyclin-dependent kinase (Cdk) sites containing phosphoserine

Mitotic cell division is controlled by cyclin-dependent kinases (Cdks), which phosphorylate hundreds of protein substrates responsible for executing the division program. Cdk inactivation and reversal of Cdk-catalyzed phosphorylation are universal requirements for completing and exiting mitosis and resetting the cell cycle machinery. Mechanisms that define the timing and order of Cdk substrate dephosphorylation remain poorly understood. Cdc14 phosphatases have been implicated in Cdk inactivation and are thought to be generally specific for Cdk-type phosphorylation sites. We show that budding yeast Cdc14 possesses a strong and unusual preference for phosphoserine over phosphothreonine at Pro-directed sites in vitro. Using serine to threonine substitutions in the Cdk consensus sites of the Cdc14 substrate Acm1, we demonstrate that phosphoserine specificity exists in vivo. Furthermore, it appears to be a conserved property of all Cdc14 family phosphatases. An invariant active site residue was identified that sterically restricts phosphothreonine binding and is largely responsible for phosphoserine selectivity. Optimal Cdc14 substrates also possessed a basic residue at the +3 position relative to the phosphoserine, whereas substrates lacking this basic residue were not effectively hydrolyzed. The intrinsic selectivity of Cdc14 may help establish the order of Cdk substrate dephosphorylation during mitotic exit and contribute to roles in other cellular processes.     

Protein phosphatases and their regulation in the control of mitosis

Cell cycle transitions depend on protein phosphorylation and dephosphorylation. The discovery of cyclin-dependent kinases (CDKs) and their mode of activation by their cyclin partners explained many important aspects of cell cycle control. As the cell cycle is basically a series of recurrences of a defined set of events, protein phosphatases must obviously be as important as kinases. However, our knowledge about phosphatases lags well behind that of kinases. We still do not know which phosphatase(s) is/are truly responsible for dephosphorylating CDK substrates, and we know very little about whether and how protein phosphatases are regulated. Here, we summarize our present understanding of the phosphatases that are important in the control of the cell cycle and pose the questions that need to be answered as regards the regulation of protein phosphatases.     

Enzyme systems involved in phosphorylation and dephosphorylation of two endogenous phosphoproteins in neuronal membranes.

Adenosine 3′:5′-monophosphate-dependent protein kinase and phosphoprotein phosphatases were solubilized by Triton X-100, from a particulate fraction of bovine cerebral cortex enriched in synaptic membranes, and partially purified. The properties of these partially purified enzymes were studied using two substrates, Protein I and Protein II, prepared from the synaptic membrane fraction, as well as the substrates protamine and histone. The results suggest that the phosphorylation of Protein I and Protein II, as well as protamine and histone, are catalyzed by a single species of cAMP-deperident protein kinase. Thus, a single peak of protein kinase activity was observed, upon DEAE-cellulose hromatography of the Triton X-100 extract of the synaptic membrane preparation, which catalyzed the phosphorylation of all four substrate proteins. Moreover, the activity of this partially purified protein kinase toward the various substrate proteins was altered in a parallel fashion, either when the protein kinase preparation was subjected to heat inactivation or pH inactivation, or when the enzyme was assayed in the presence of various concentrations of cyclic nucleotides or of a protein kinase modulator. The individual protein substrates acted as competitive inhibitors with respect to one another. Upon sucrose density gradient centrifugation, the protein kinase activity toward the various substrates sedimented as a single peak. Finally, the relative specific activities toward the various substrates did not change significantly during a 2000-fold purification of the enzyme. In contrast to these observations with protein kinase, two peaks of protein phosphatase activity, with markedly different specificities toward Protein I and Protein II, were found upon DEAE-cellulose and Bio-Gel P-200 column chromatography of the Triton X-100 extract of the synaptic membrane fractions. One peak catalyzed the dephosphorylation of Phosphoprotein I but not of Phosphoprotein II, whereas the other peak catalyzed the dephosphorylation of Phosphoprotein II but not of Phosphoprotein I. The dephosphorylation of Phosphoprotein I by Phosphoprotein I phosphatase was not affected by adenosine 3':5'-monophosphate, whereas the dephosphorylation of Phosphoprotein II by Phosphoprotein II phosphatase required the presence of this nucleotide. Moreover, the two phosphatases differed from one another with respect to Stokes' radius as well as sedimentation coefficient.     

The protein phosphatases involved in cellular regulation. Glycolysis, gluconeogenesis and aromatic amino acid breakdown in rat liver

The identities of the protein phosphatases involved in the regulation of hepatic glycolysis, gluconeogenesis and aromatic amino acid breakdown were investigated using 6-phosphofructo-1-kinase, fructose-1,6-bisphosphatase, L-pyruvate kinase, phenylalanine hydroxylase and the bifunctional enzyme 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase as substrates. Purified preparations of protein phosphatases-1, 2A, 2B and 2C exhibited activity towards all five substrates in vitro, although phosphatases-1 and 2B were only weakly active. Studies in liver extracts using inhibitor-2 and trifluoperazine, which inhibit protein phosphatase-1 and 2B, respectively, confirmed that these phosphatases are unlikely to be important in dephosphorylating these substrates in vivo. Sequential fractionation of rat liver extracts by anion-exchange chromatography and gel-filtration failed to resolve any protein phosphatases acting on each substrate, apart from protein phosphatases-2A and 2C. The present results, together with those described in the following paper (in this journal) indicate that under the assay conditions used, protein phosphatase-2A is the most powerful phosphatase acting on each substrate, although protein phosphatase-2C contributes a significant percentage of the activity towards 6-phosphofructo-1-kinase. No clear evidence was obtained for a role of metabolites in the regulation of dephosphorylation of the five substrates. This study reinforces our contention that only a few serine-specific and threonine-specific protein phosphatase catalytic subunits participate in cellular regulation.     

Defining SH2 domain and PTP specificity by screening combinatorial peptide libraries

Src homology 2 (SH2) domains mediate protein-protein interactions by recognizing short phosphotyrosyl (pY) peptide motifs in their partner proteins. Protein tyrosine phosphatases (PTPs) catalyze the dephosphorylation of pY proteins, counteracting the protein tyrosine kinases. Both types of proteins exhibit primary sequence specificity, which plays at least a partial role in dictating their physiological interacting partners or substrates. A combinatorial peptide library method has been developed to systematically assess the sequence specificity of SH2 domains and PTPs. A "one-bead-one-compound" pY peptide library is synthesized on 90-microm TentaGel beads and screened against an SH2 domain or PTP of interest for binding or catalysis. The beads that carry the tightest binding sequences against the SH2 domain or the most efficient substrates of the PTP are selected by an enzyme-linked assay and individually sequenced by a partial Edman degradation/mass spectrometry technique. The combinatorial method has been applied to determine the sequence specificity of 8 SH2 domains from Src and Csk kinases, adaptor protein Grb2, and phosphatases SHP-1, SHP-2, and SHIP1 and a prototypical PTP, PTP1B.