PTEN catalysis of phospholipid dephosphorylation reaction follows a two-step mechanism in which the conserved aspartate-92 does not function as the general acid--mechanistic analysis of a familial Cowden disease-associated PTEN mutation

PTEN exerts its tumour suppressor function by dephosphorylating the phospholipid second messenger phosphatidylinositol-3,4,5-trisphosphate (PIP(3)). Herein, we demonstrate that the PTEN-catalysed PIP(3) dephosphorylation reaction involves two-steps: (i) formation of a phosphoenzyme intermediate (PE) in which Cys-124 in the active site is thiophosphorylated, and (ii) hydrolysis of PE. For protein tyrosine- and dual-specificity phosphatases, catalysis requires the participation of a conserved active site aspartate as the general acid in Step 1. Its mutation to alanine severely limits PE formation. However, mutation of the homologous Asp-92 in PTEN does not significantly limit PE formation, indicating that Asp-92 does not act as the general acid. G129E is a common germline PTEN mutations found in Cowden syndrome patients. Mechanistic analysis reveals that this mutation inactivates PTEN by both significantly slowing down Step 1 and abolishing the ability to catalyse Step 2. Taken together, our results highlight the mechanistic similarities and differences between PTEN and the conventional protein phosphatases and reveal how a disease-associated mutation inactivates PTEN.     

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.     

Aspartic-129 is an essential residue in the catalytic mechanism of the low Mr phosphotyrosine protein phosphatase

The crystal structure of the bovine liver low M_r phosphotyrosine protein phosphatase suggests the involvement of aspartic acid-129 in enzyme catalysis. The Asp-129 to alanine mutant has been prepared by oligonucleotide-directed mutagenesis of a synthetic gene coding for the enzyme. The purified mutant elicited an highly reduced specific activity (about 0.04% of the activity of the wild-type) and a native-like fold, as judged by ¹H NMR spectroscopy. The kinetic analysis revealed that the mutant is able to bind the substrate and a competitive inhibitor, such as inorganic phosphate. Moreover, trapping experiments demonstrated it maintains the ability to form the E-P covalent complex. The Asp-129 to alanine mutant shows extremely reduced enzyme phosphorylation (k₂) and dephosphorylation (k₃) kinetic constant values as compared to the wild-type enzyme. The data reported indicate that aspartic acid-129 is likely to be involved both in the first step and in the rate-limiting step of the catalytic mechanism, i.e. the nucleophilic attack of the phosphorylated intermediate.     

Comparison of two forms of pig heart phosphoprotein phosphatase.

A phosphoprotein phosphatase (phosphoprotein phosphohydrolase, EC 3.1.3.16) was partially purified from pig heart using as substrate H2B histone which had been phosphorylated at Ser-32 and Ser-36 by adenosine 3',5'-monophosphate-dependent protein kinase (EC 2.7.1.37). The enzyme had a molecular weight of approx. 250 000 and was converted to a smaller form with a molecular weight of approx. 30 000 upon treatment with ethanol. Phosphorylase alpha (EC 2.4.1.1) and phosphorylated H1 histone also served as substrates for both forms of the enzyme. The conversion of the large form of the enzyme to the small form decreased the phosphohistone phosphatase activity to 25-50% with a concomitant 7-fold increase in the phosphorylase alpha phosphatase activity. Ser-36 phosphate was removed 6- and 15-fold more rapidly than was Ser-32 phosphate by the large and small forms of the enzyme, respectively. Among Ser-36-containing tryptic phosphopeptides derived from phosphorylated H2B histone, Lys-Glu-Ser(P)-Tyr-Ser-Val-Tyr was the shortest phosphopeptide which was dephosphorylated at a significant reaction rate with the phosphoprotein phosphatase. The Km values for phosphorylated H2B histone and the tryptic phosphopeptide were 23.7 micron and 187.1 micron, respectively, with the large form, and 81.4 micron and 90.0 micron, respectively, with the small form of the enzyme.     

The presence of a heat-stable activator of phosphoprotein phosphatase for the dephosphorylation of phosphorylated histone in rabbit liver.

A heat-stable protein activator of phosphoprotein phosphatase for the dephosphorylation of phosphorylated histone has been identified in rabbit liver. The protein activator is different than the previously observed heat-stable protein inhibitor of rabbit liver phosphoprotein phosphatase. It stimulates the dephosphorylation of histone by increasing the Vmax of the reaction as well as decreasing the Km for histone.     

Mechanistic studies of phosphoserine phosphatase, an enzyme related to P-type ATPases

Phosphoserine phosphatase belongs to a new class of phosphotransferases forming an acylphosphate during catalysis and sharing three motifs with P-type ATPases and haloacid dehalogenases. The phosphorylated residue was identified as the first aspartate in the first motif (DXDXT) by mass spectrometry analysis of peptides derived from the phosphorylated enzyme treated with NaBH(4) or alkaline [(18)O]H(2)O. Incubation of native phosphoserine phosphatase with phosphoserine in [(18)O]H(2)O did not result in (18)O incorporation in residue Asp-20, indicating that the phosphoaspartate is hydrolyzed, as in P-type ATPases, by attack of the phosphorus atom. Mutagenesis studies bearing on conserved residues indicated that four conservative changes either did not affect (S109T) or caused a moderate decrease in activity (G178A, D179E, and D183E). Other mutations inactivated the enzyme by >80% (S109A and G180A) or even by >/=99% (D179N, D183N, K158A, and K158R). Mutations G178A and D179N decreased the affinity for phosphoserine, suggesting that these residues participate in the binding of the substrate. Mutations of Asp-179 decreased the affinity for Mg(2+), indicating that this residue interacts with the cation. Thus, investigated residues appear to play an important role in the reaction mechanism of phosphoserine phosphatase, as is known for equivalent residues in P-type ATPases and haloacid dehalogenases.     

Selective Dephosphorylation of the Subunits of Skeletal Muscle Calcium Channels by Purified Phosphoprotein Phosphatases

Abstract: Multiple sites on the α1 and β subunits of purified skeletal muscle calcium channels are phosphorylated by cyclic AMP-dependent protein kinase, resulting in three different tryptic phosphopeptides derived from each subunit. Phosphoprotein phosphatases dephosphorylated these sites selectively. Phosphoprotein phosphatase 1 (PP1) and phosphoprotein phosphatase 2A (PP2A) dephosphorylated both α1 and β subunits at similar rates, whereas calcineurin dephosphorylated β subunits preferentially. PP1 dephosphorylated phosphopeptides 1 and 2 of the α1 subunit more rapidly than phosphopeptide 3. In contrast, PP2A dephosphorylated phosphopeptide 3 of the α1 subunit preferentially. All three phosphoprotein phosphatases preferentially dephosphorylated phosphopeptide 1 of the β subunit and dephosphorylated phosphopeptides 2 and 3 more slowly. Mn²⁺ increased the rate and extent of dephosphorylation of all sites by calcineurin so that >80% dephosphorylation of both α1 and β sub-units was obtained. The results demonstrate selective dephosphorylation of different phosphorylation sites on the α1 and β subunits of skeletal muscle calcium channels by the three principal serine/threonine phosphoprotein phosphatases.     

Transition state analysis and requirement of Asp-262 general acid/base catalyst for full activation of dual-specificity phosphatase MKP3 by extracellular regulated kinase

Dual-specificity phosphatase MKP3 down-regulates mitogenic signaling through dephosphorylation of extracellular regulated kinase (ERK). Unlike a simple substrate-enzyme interaction, the noncatalytic, amino-terminal domain of MKP3 can bind efficiently to ERK, leading to activation of the phosphatase catalytic domain by as much as 100-fold toward exogenous substrates. It has been suggested that ERK activates MKP3 through the stabilization of the active phosphatase conformation, enabling general acid catalysis. Here, we investigated whether Asp-262 of MKP3 is the bona fide general acid and evaluated its contribution to the catalytic steps activated by ERK. Using site-directed mutagenesis, pH rate and Br?nsted analyses, kinetic isotope effects, and steady-state and rapid reaction kinetics, Asp-262 was identified as the authentic general acid catalyst, donating a proton to the leaving group oxygen during P-O bond cleavage. Kinetic isotope effects [(18)(V/K)(bridge), (18)(V/K)(nonbridge), and (15)(V/K)] were evaluated for the effect of ERK and of the D262N mutation on the transition state of the phosphoryl transfer reaction. The patterns of the three isotope effects for the reaction with native MKP3 in the presence of ERK are indicative of a reaction where the leaving group is protonated in the transition state, whereas in the D262N mutant, the leaving group departs as the anion. Even without general acid catalysis, the D262N mutant reaction is activated by ERK through increased phosphate affinity ( approximately 8-fold) and the partial stabilization of the transition state for phospho-enzyme intermediate formation ( approximately 4-fold). Based on these analyses, we estimate that dephosphorylation of phosphorylated ERK by the D262N mutant is >1000-fold lower than by native, activated MKP3. Also, the kinetic results suggest that Asp-262 functions as a general base during thiol-phosphate intermediate hydrolysis.     

Isolation and characterization of an alkaline phosphatase from pea thylakoids

Endogenous dephosphorylation of the light-harvesting chlorophyll-protein complex of photosystem II in pea (Pisum sativum, L. cv Progress 9) thylakoids drives the state 2 to state 1 transition; the responsible enzyme is a thylakoid-bound, fluoride-sensitive phosphatase with a pH optimum of 8.0 (Bennett J [1980] Eur J Biochem 104: 85-89). An enzyme with these characteristics was isolated from well-washed thylakoids. Its molecular mass was estimated at 51.5 kD, and this monomer was catalytically active, although the activity was labile. The active site could be labeled with orthophosphate at pH 5.0. High levels of alkaline phosphatase activity were obtained with the assay substrate, 4-methylumbelliferyl phosphate (350 micromoles per minute per milligram purified enzyme). The isolated enzyme functioned as a phosphoprotein phosphatase toward phosphorylated histone III-S and phosphorylated, photosystem II-enriched particles from pea, with typical activities in the range of 200 to 600 picomoles per minute per milligram enzyme. These activities all had a pH optimum of 8.0 and were fluoride sensitive. The enzyme required magnesium ion for maximal activity but was not dependent on this ion. Evidence supporting a putative function for this phosphatase in dephosphorylation of thylakoid proteins came from the inhibition of this process by a polyclonal antibody preparation raised against the partially purified enzyme.     

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.     

Insights into the catalytic mechanism of human sEH phosphatase by site-directed mutagenesis and LC-MS/MS analysis

We have recently reported that human soluble epoxide hydrolase (sEH) is a bifunctional enzyme with a novel phosphatase enzymatic activity. Based on a structural relationship with other members of the haloacid dehalogenase superfamily, the sEH N-terminal phosphatase domain revealed four conserved sequence motifs, including the proposed catalytic nucleophile D9, and several other residues potentially implicated in substrate turnover and/or Mg²⁺ binding. To enlighten the catalytic mechanism of dephosphorylation, we constructed sEH phosphatase active-site mutants by site-directed mutagenesis. A total of 18 mutants were constructed and recombinantly expressed in Escherichia coli as soluble proteins, purified to homogeneity and subsequently analysed for their kinetic parameters. A replacement of residues D9, K160, D184 or N189 resulted in a complete loss of phosphatase activity, consistent with an essential function for catalysis. In contrast, a substitution of D11, T123, N124 and D185 leads to sEH mutant proteins with altered kinetic properties. We further provide evidence of the formation of an acylphosphate intermediate on D9 by liquid chromatography-tandem mass spectrometry based on the detection of homoserine after NaBH₄ reduction of the phosphorylated enzyme, which identifies D9 as the catalytic nucleophile. Surprisingly, we could only show such homoserine formation using the D11N mutant, which strongly suggests D11 to be involved in the acylphosphate hydrolysis. In the D11 mutant, the second catalytic step becomes rate limiting, which then allows trapping of the labile intermediate. Substrate turnover in the presence of ¹⁸H₂O revealed that the nucleophilic attack during the second reaction step occurs at the acylphosphate phosphorous. Based on these findings, we propose a two-step catalytic mechanism of dephosphorylation that involves the phosphate substrate hydrolysis by nucleophilic attack by the catalytic nucleophile D9 followed by hydrolysis of the acylphosphate enzyme intermediate supported by D11.     

Separation of phosphoprotein isotypes having the same number of phosphate groups using phosphate-affinity SDS-PAGE

Herein, we demonstrate the separation of phosphoprotein isotypes having the same number of phosphate groups using phosphate-affinity SDS-PAGE. The phosphate-affinity site is a polyacrylamide-bound Phos-tag that enables the mobility shift detection of phosphoproteins from their nonphosphorylated counterparts. As the first practical example of the separation, we characterized the monophosphorylated Tau isotypes by each of three tyrosine kinases, c-Abl, MET, and Fyn. Each monophosphoisotype phosphorylated at the Tyr-394, Tyr-197, or Tyr-18 was detected as three distinct migration bands. As a further application, we extended this technique to the mobility shift analysis of His and Asp phosphoisotypes in the Sinorhizobium meliloti FixL/FixJ two-component system. FixL is autophosphorylated at the His-285 with ATP, and the phosphate group is transferred to the Asp-54 of FixJ and subsequently removed by the FixL phosphatase activity. Using this method, we first performed simultaneous detection of the phosphorylated and nonphosphorylated isotypes of FixL and FixJ generated in their phosphotransfer reaction in vitro. As a result, a monophosphoisotype of FixL containing the phosphorylated His residue was confirmed. As for FixJ, on the other hand, two monophosphoisotypes were detected as two distinct migration bands. One is a well-known isotype phosphorylated at the Asp-54. The other is a novel isotype phosphorylated at the His-84.     

Purification, properties, and substrate specificities of phosphoprotein phosphatase(s) from rabbit liver.

The phosphoprotein phosphatase(s) acting on muscle phosphorylase a was purified from rabbit liver by acid precipitation, high speed centrifugation, chromatography on DEAE-Sephadex A-50, Sephadex G-75, and Sepharose-histone. Enzyme activity was recovered in the final step as two distinct peaks tentatively referred to as phosphoprotein phosphatases I and II. Each phosphatase showed a single broad band when examined by sodium dodecyl sulfate gel electrophoresis; the molecular weights derived by this method were approximately 30,500 for phosphoprotein phosphatase I and 34,000 for phosphoprotein phosphatase II. The s20, w value for each enzyme was 3.40. Using this value and values for the Stokes radii, the molecular weight for each enzyme was calculated to be 34,500. Both phosphatases, in addition to catalyzing the conversion of phosphorylase a to b, also catalyzed the dephosphorylation of glycogen synthase D, activated phosphorylase kinase, phosphorylated histone, phosphorylated casein, and the phosphorylated inhibitory component of troponin (TN-I). The relative activities of the phosphatases with respect to phosphorylase a, glycogen synthase D, histone, and casein remained essentially constant throughout the purification. The activities of both phosphatases with different substrates decreased in parallel when they were denatured by incubation at 55 degrees and 65 degrees. The Km values of phosphoprotein phosphatase I for phosphorylase a, histone, and casein were lower than the values obtained for phosphoprotein phosphatase II. With glycogen synthase D as substrate, each enzyme gave essentially the same Km value. Utilizing either enzyme, it was found that activity toward a given substrate was inhibited competitively by each of the alternative substrates. The results suggest that phosphoprotein phosphatases I and II are each active toward all of the substrates tested.     

Mutant phosphatidate phosphatase Pah1-W637A exhibits altered phosphorylation,membrane association,and enzyme function in yeast

The Saccharomyces cerevisiae PAH1-encoded phosphatidate (PA) phosphatase, which catalyzes the dephosphorylation of PA to produce diacylglycerol, controls the bifurcation of PA into triacylglycerol synthesis and phospholipid synthesis. Pah1 is inactive in the cytosol as a phosphorylated form and becomes active on the membrane as a dephosphorylated form by the Nem1–Spo7 protein phosphatase. We show that the conserved Trp-637 residue of Pah1, located in the intrinsically disordered region, is required for normal synthesis of membrane phospholipids, sterols, triacylglycerol, and the formation of lipid droplets. Analysis of mutant Pah1-W637A showed that the tryptophan residue is involved in the phosphorylation-mediated/dephosphorylation-mediated membrane association of the enzyme and its catalytic activity. The endogenous phosphorylation of Pah1-W637A was increased at the sites of the N-terminal region but was decreased at the sites of the C-terminal region. The altered phosphorylation correlated with an increase in its membrane association. In addition, membrane-associated PA phosphatase activity in vitro was elevated in cells expressing Pah1-W637A as a result of the increased membrane association of the mutant enzyme. However, the inherent catalytic function of Pah1 was not affected by the W637A mutation. Prediction of Pah1 structure by AlphaFold shows that Trp-637 and the catalytic residues Asp-398 and Asp-400 in the haloacid dehalogenase-like domain almost lie in the same plane, suggesting that these residues are important to properly position the enzyme for substrate recognition at the membrane surface. These findings underscore the importance of Trp-637 in Pah1 regulation by phosphorylation, membrane association of the enzyme, and its function in lipid synthesis.     

Expression, generation, and purification of unphosphorylated and phospho-Ser-380/Thr-382/Thr-383 form of recombinant PTEN phosphatase

The dual specificity phosphatase PTEN exerts its tumour suppressor and cell-migration regulatory functions by dephosphorylating the phospholipid substrate, phosphatidylinositol-3,4,5-trisphosphate (PI(3,4,5)P(3)), and phosphotyrosine protein substrates. PTEN functions are regulated by phospholipid binding, interactions with other cellular proteins and phosphorylation at multiple sites. Precisely, how the phosphorylation and binding events modulate PTEN activity and structure remains mostly unclear. Detailed studies of this issue require the availability of significant quantity of both the unphosphorylated and phosphorylated forms of purified recombinant PTEN. Here, we describe the successful expression and purification of recombinant rat PTEN using a baculovirus-infected Spodoptera frugiperda (Sf9) cell expression system. The recombinant PTEN was purified to near homogeneity using four sequential column chromatographic steps. The specific enzymatic activity of the purified preparation in dephosphorylating PI(3,4,5,)P(3) and the artificial phosphotyrosine substrate poly(Glu/Tyr) are 6.7 nmol/min/microg and 0.006 pmol/min/microg, respectively. Intriguingly, similar to PTEN expressed in mammalian cells, the recombinant PTEN was phosphorylated in the infected insect cells at Ser-380, Thr-382, and Thr-383 at the C-terminal tail. Treatment with alkaline phosphatase fully dephosphorylated these sites. After the treatment, the unphosphorylated PTEN and alkaline phosphatase could be separated by ion exchange column chromatography. The availability of the phosphorylated and unphosphorylated forms of recombinant PTEN permits future investigations into the three-dimensional structures of the phosphorylated and unphosphorylated forms of PTEN, and the role of phosphorylation in regulating PTEN activity, phospholipid- and protein-binding affinities.     

Inhibition of membrane phosphotyrosyl-protein phosphatase activity by vanadate

We have investigated the effect of vanadate on the phosphoserine- and phosphotyrosine-specific phosphoprotein phosphatase activities of A-431 cell membranes and have found that micromolar concentrations of vanadate strongly inhibit the membrane-dependent dephosphorylation of histones containing phosphotyrosine but that they do not inhibit the dephosphorylation of histones containing phosphoserine and phosphothreonine. In addition, the dephosphorylation of endogeneous membrane proteins of A-431 cells (which are known to be phosphorylated at tyrosine residues) was inhibited by vanadate. These results show that vanadate is a potent and selective inhibitor of phosphotyrosyl-protein phosphatase.     

Structural and mechanistic basis for the activation of a low-molecular weight protein tyrosine phosphatase by adenine

Although the activation of low-molecular weight protein tyrosine phosphatases by certain purines and purine derivatives was first described three decades ago, the mechanism of this rate enhancement was unknown. As an example, adenine activates the yeast low-molecular weight protein tyrosine phosphatase LTP1 more than 30-fold. To examine the structural and mechanistic basis of this phenomenon, we have determined the crystal structure of yeast LTP1 complexed with adenine. In the crystal structure, an adenine molecule is found bound in the active site cavity, sandwiched between the side chains of two large hydrophobic residues at the active site. Hydrogen bonding to the side chains of other active site residues, as well as some water-mediated hydrogen bonds, also helps to fix the position of the bound adenine molecule. An ordered water was found in proximity to the bound phosphate ion present in the active site, held by hydrogen bonding to N3 of adenine and Odelta1 of Asp-132. On the basis of the crystal structure, we propose that this water molecule is the nucleophile that participates in the dephosphorylation of the phosphoenzyme intermediate. Solvent isotope effect studies show that there is no rate-determining transfer of a solvent-derived proton in the transition state for the dephosphorylation of the phosphoenzyme intermediate. Such an absence of general base catalysis of water attack is consistent with the stability of the leaving group, namely, the thiolate anion of Cys-13. Consequently, adenine activates the enzyme by binding and orienting a water nucleophile in proximity to the phosphoryl group of the phosphoenzyme intermediate, thus increasing the rate of the dephosphorylation step, a step that is normally the rate-limiting step of this enzymatic reaction.     

Purification and characterization of a phosphoprotein phosphatase from bovine adrenal cortex.

A phosphoprotein phosphatase which is active against chemically phosphorylated protamine has been purified about 500-fold from bovine adrenal cortex. The enzyme has a pH optimum between 7.5 and 8.0, and has an apparent Km for phosphoprotamine of about 50 muM. The hydrolysis of phosphoprotamine is stimulated by salt, and by Mn2+. Hydrolysis of phosphoprotamine is inhibited by ATP, ADP, AMP, and Pi, but is not affected by AMP or cyclic GMP. The purified phosphoprotein phosphatase preparation also dephosphorylates p-nitrophenyl phosphate and phosphohistone, and catalyzes the inactivation of liver phosphorylase, the inactivation of muscle phosphorylase a (and its conversion to phosphorylase b), and the inactivation of muscle phosphorylase b kinase. Phosphatase activities against phosphoprotamine and muscle phosphorylase a copurify over the last three stages of purification. Phosphoprotamine inhibits phosphorylase phosphatase activity, and muscle phosphorylase a inhibits the dephosphorylation of phosphoprotamine. These results suggest that one enzyme possesses both phosphoprotamine phosphatase and phosphorylase phosphatase activities. The stimulation of phosphorylase phosphatase activity, but not of phosphoprotamine phosphatase activity, by caffeine and by glucose, suggests that the different activities of this phosphoprotein phosphatase may be regulated separately.     

Myosin phosphatase is inactivated by caspase-3 cleavage and phosphorylation of myosin phosphatase targeting subunit 1 during apoptosis

In nonapoptotic cells, the phosphorylation level of myosin II is constantly maintained by myosin kinases and myosin phosphatase. During apoptosis, caspase-3–activated Rho-associated protein kinase I triggers hyperphosphorylation of myosin II, leading to membrane blebbing. Although inhibition of myosin phosphatase could also contribute to myosin II phosphorylation, little is known about the regulation of myosin phosphatase in apoptosis. In this study, we have demonstrated that, in apoptotic cells, the myosin-binding domain of myosin phosphatase targeting subunit 1 (MYPT1) is cleaved by caspase-3 at Asp-884, and the cleaved MYPT1 is strongly phosphorylated at Thr-696 and Thr-853, phosphorylation of which is known to inhibit myosin II binding. Expression of the caspase-3 cleaved form of MYPT1 that lacked the C-terminal end in HeLa cells caused the dissociation of MYPT1 from actin stress fibers. The dephosphorylation activity of myosin phosphatase immunoprecipitated from the apoptotic cells was lower than that from the nonapoptotic control cells. These results suggest that down-regulation of MYPT1 may play a role in promoting hyperphosphorylation of myosin II by inhibiting the dephosphorylation of myosin II during apoptosis.