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.     

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.     

Comparison of the substrate specificities of protein phosphatases involved in the regulation of glycogen metabolism in rabbit skeletal muscle.

Muscle extracts were subjected to fractionation with ethanol, chromatography on DEAE-cellulose, precipitation with (NH4)2SO4 and gel filtration on Sephadex G-200. These fractions were assayed for protein phosphatase activities by using the following seven phosphoprotein substrates: phosphorylase a, glycogen synthase b1, glycogen synthase b2, phosphorylase kinase (phosphorylated in either the alpha-subunit or the beta-subunit), histone H1 and histone H2B. Three protein phosphatases with distinctive specificities were resolved by the final gel-filtration step and were termed I, II and III. Protein phosphatase-I, apparent mol.wt. 300000, was an active histone phosphatase, but it accounted for only 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities and 2-3% of the phosphorylase kinase phosphatase and phosphorylase phosphatase activity recovered from the Sephadex G-200 column. Protein phosphatase-II, apparent mol.wt. 170000, possessed histone phosphatase activity similar to that of protein phosphatase-I. It possessed more than 95% of the activity towards the alpha-subunit of phosphorylase kinase that was recovered from Sephadex G-200. It accounted for 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activity, but less than 5% of the activity against the beta-subunit of phosphorylase kinase and 1-2% of the phosphorylase phosphatase activity recovered from Sephadex G-200. Protein phosphatase-III was the most active histone phosphatase. It possessed 95% of the phosphorylase phosphatase and beta-phosphorylase kinase phosphatase activities, and 75% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities recovered from Sephadex G-200. It accounted for less than 5% of the alpha-phosphorylase kinase phosphatase activity. Protein phosphatase-III was sometimes eluted from Sephadex-G-200 as a species of apparent mol.wt. 75000(termed IIIA), sometimes as a species of mol.wt. 46000(termed IIIB) and sometimes as a mixture of both components. The substrate specificities of protein phosphatases-IIA and -IIB were identical. These findings, taken with the observation that phosphorylase phosphatase, beta-phosphorylase kinase phosphatase, glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities co-purified up to the Sephadex G-200 step, suggest that a single protein phosphatase (protein phosphatase-III) catalyses each of the dephosphorylation reactions that inhibit glycogenolysis or stimulate glycogen synthesis. This contention is further supported by results presented in the following paper [Cohen, P., Nimmo, G.A. & Antoniw, J.F. (1977) Biochem. J. 1628 435-444] which describes a heat-stable protein that is a specific inhibitor of protein phosphatase-III.     

Phosphoprotein Phosphatase of Soybean Hypocotyls: PURIFICATION, PROPERTIES, AND SUBSTRATE SPECIFICITIES

A soybean histone-type protein kinase was used to prepare ³²P-labeled histone H1 as substrate for purification and characterization of a phosphoprotein phosphatase (EC 3.1.3.16) from soybean hypocotyls. The phosphatase has been purified 169-fold by ammonium sulfate fractionation, ethanol precipitation, and chromatography on Sephadex G-150, DEAE-Sephadex A-25 and Sephadex G-100. The activity of the phosphoprotein phosphatase is distinct from that of acid and alkaline phosphatases (EC 3.1.3.1) as well as from that of nucleotidases. The final enzyme preparation does not contain histone protease activity, although it can be detected during the early stages of purification. The protease(s) apparently can attack phosphorylated histone H1, indicating that phosphorylation does not protect the protein against proteolytic degradation.     

Phosphorylation of calf thymus H1 histone by muscle glycogen phosphorylase kinase

Muscle glycogen phosphorylase kinase [EC 2.7.1.38] has the ability to phosphorylate five fractions of calf thymus histone. H1 histone is the most preferable substrate, and maximally about 1.3 mol of phosphate is incorporated into every mole of this histone. This reaction absolutely depends on CA2+, and the molecular activity is about one third of that of cyclic AMP-dependent protein kinase (protein kinase A). The affinity of phosphorylase kinase for H1 histone is higher than that of protein kinase A. Calmodulin stimulates this histone phosphorylation. Analysis of the N-bromosuccinimide-bisected fragments of fully phosphorylated H1 histone has revealed that the enzyme phosphorylates mostly seryl residues in both amino- and carboxyl-terminal portions, although phosphorylation of the carboxyl-terminal portion is twice as much as that of the amino-terminal portion. Fingerprint analysis indicates that the phosphorylation sites in H1 histone for this enzyme are different from the sites phosphorylated by protein kinase A. This catalytic activity also differs from that of a newly found multifunctional protein kinase which may be activated by the simultaneous presence of Ca2+ and phospholipid.     

A multisubstrate Ca2+ and cyclic nucleotide independent kinase from vascular smooth muscle: modulation of activity by polycations

A multisubstrate Ca2+ and cyclic nucleotide independent kinase (Mr = 47,000) was purified from bovine aortic smooth muscle. Phosphorylation of glycogen synthase by this enzyme was polycation modulable. Low concentrations of polylysine (0.04-0.16 microM) stimulated phosphorylation 2-7 fold, whereas higher concentrations suppressed phosphorylation. Glycogen synthase converted to its glucose 6-PO4 dependent form following phosphorylation in either the presence (7 mol 32P/mol synthase) or absence (4 mol 32P/mol synthase) of polylysine: extent of conversion correlated to extent of phosphorylation. Seven of 14 potential substrates tested were phosphorylated: kinase activity was greatest for phosvitin followed by casein, the receptor protein from type 2 cAMP-kinase, histone H2b, phosphorylase kinase, glycogen synthase, and myocardial myosin light chains. Phosphorylation of phosvitin or synthase was inhibited by heparin (1/2 maximally by 0.5 microgram/ml without salt and 37 micrograms/ml with 150 mM NaCl). The results suggest that the enzyme may participate in regulating arterial glycogen metabolism and that such regulation may be modulated by polycationic and polyanionic effectors.     

Rabbit muscle glycogen-bound phosphoprotein phosphatases: substrate specificities and effects of inhibitor-1

A phosphoprotein phosphatase which has an apparent molecular weight of 240,000 was partially purified (500-fold) from the glycogen-protein complex of rabbit skeletal muscle. The enzyme exhibited broad substrate specificity as it dephosphorylated phosphorylase, phosphohistones, glycogen synthase, phosphorylase kinase, regulatory subunit of cAMP-dependent protein kinase, and phosphatase inhibitor 1. The phosphatase showed high specificity towards dephosphorylation of the beta-subunit of phosphorylase kinase and site 2 of glycogen synthase. With the latter substrate, the presence of phosphate in sites 1a and 1b decreased the apparent Vmax, perhaps by inhibiting the dephosphorylation of site 2. The phosphorylated form of inhibitor 1 did not significantly inhibit this high-molecular-weight phosphatase. However, an inhibitor 1-sensitive phosphatase activity could be derived from this preparation by limited trypsinization. Furthermore, greater than 70% of the phosphatase activity in skeletal muscle extracts and in the glycogen-protein complex was insensitive to inhibitor 1. Limited trypsinization of each fraction obtained from the phosphatase purification increased the total activity (1.5- to 2-fold) and converted the enzyme into a form which was inhibited by inhibitor 1. The results suggest that inhibitor 1-sensitive phosphatase may be a proteolyzed enzyme.     

p34cdc2 phosphorylation sites in histone H1 are dephosphorylated by protein phosphatase 2A1.

The protein phosphatase activity in rat liver cytosol or nuclear extracts that dephosphorylates histone H1 which has been phosphorylated by p34cdc2 is inhibited completely by okadaic acid, but unaffected by inhibitor-2 or magnesium ions, demonstrating that the only enzyme in this tissue capable of dephosphorylating this substrate is a type 2A phosphatase. Fractionation of the cytosol by anion-exchange chromatography and gel filtration demonstrated that histone H1 phosphatase activity coeluted with the major species of protein phosphatase 2A, termed PP2A1 and PP2A2. PP2A1 was the most active histone H1 phosphatase, its histone phosphatase phosphorylase phosphatase activity ratio being 6-fold higher than PP2A2 and 30-fold higher than the free catalytic subunit PP2AC. It is concluded that PP2A1 is likely to be the enzyme which dephosphorylates p34cdc2-labelled histone H1 in vivo and that the A and B subunits which interact with PP2AC in this species each play a key role in facilitating dephosphorylation of this substrate. The results demonstrate that PP2A, in addition to being involved in suppressing the activation of p34cdc2 in vivo, can also function to reverse at least one of its actions.     

Some properties of purified phosphoprotein phosphatases from rabbit liver.

The activity of two purified homogeneous phosphoprotein phosphatases types P I and P II) (phosphoprotein phosphohydrolase, EC 3.1.3.16) from rabbit liver (Khandelwal, R.L., Vandenheede, J.R., and Krebs, E.G. (1976) J. Biol. Chem. 251, 4850-4858) were examined in the presence of divalent cations, Pi, PPi, nucleotides, glycolytic intermediates and a number of other compounds using phosphorylase a, glycogen synthase D and phosphorylated histone as substrates. Enzyme activities were usually inhibited by divalent cations with all substrates; the inhibition being more pronounced with phosphorylase a. Zn2+ was the most potent inhibitor among the divalent cations tested. The enzyme was competitively inhibited by PPi (Ki = 0.1 mM for P I and 0.3 mM for PII), Pi (Ki = 15 mM for P I and 19.8 mM for P II) and p-nitrophenyl phosphate (Ki = 1 mM and 1.4 mM for P I and P II, respectively) employing phosphorylase a as the substrate. The compounds along with a number of others (Na2SO4, citrate, NaF and EDTA) also inhibited the enzyme activity with the other two substrates. Severe inhibition of the enzyme was also observed in the presence of the adenine and uridine nucleotides; monophosphate nucleotides being more inhibitory with phosphorylase a, whereas the di- and triphosphate nucleotides showed more inhibition with glycogen synthase D and phosphorylated histone. Cyclic AMP had no significant effect on enzyme activity with all the substrates tested. Phosphorylated metabolites did not show any marked effect on the enzyme activity with phosphorylase a as the substrate.     

Comparison of the substrate specificity of adenosine 3':5'-monophosphate- and guanosine 3':5'-monophosphate-dependent protein kinases. Kinetic studies using synthetic peptides corresponding to phosphorylation sites in histone H2B.

The substrate specificities of cyclic GMP-dependent and cyclic AMP-dependent protein kinases have been compared by kinetic analysis using synthetic peptides as substrates. Both enzymes catalyzed the transfer of phosphate from ATP to calf thymus histone H2B, as well as to two synthetic peptides, Arg-Lys-Arg-Ser32-Arg-Lys-Glu and Arg-Lys-Glu-Ser36-Tyr-Ser-Val, corresponding to the amino acid sequences around serine 32 and serine 36 in histone H2B. Serine 38 in the latter peptide was not phosphorylated by either enzyme. Cyclic GMP-dependent kinase and cyclic AMP-dependent kinase catalyzed the incorporation of 1.1 and 2.0 mol of phosphate/mol of histone H2B, respectively. The phosphorylation of histone H2B, respectively. The phosphorylation of histone H2B by cyclic GMP-dependent kinase showed two distinct optima as the magnesium concentration was increased. However, the phosphorylation of either synthetic peptide by this enzyme was depressed at high magnesium concentrations. As the pH of reaction mixtures was elevated from pH 6 to pH 9, the rate of phosphorylation of Arg-Lys-Arg-Ser32-Arg-Lys-Glu by cyclic GMP-dependent kinase continually increased. Acetylation of the NH2 terminus of the peptide did not qualitatively affect this pH profile, but did increase the Vmax value of the enzyme 3-fold. The apparent Km and Vmax values for the phosphorylation of Arg-Lys-Arg-Ser32-Arg-Lys-Glu by cyclic GMP-dependent kinase were 21 microM and 4.4 mumol/min/mg, respectively. The synthetic peptide Arg-Lys-Glu-Ser36-Tyr-Ser-Val was a relatively poor substrate for cyclic GMP-dependent kinase, exhibiting a Km value of 732 microM, although the Vmax was 12 micromol/min/mg. With histone H2B as substrate for the cyclic GMP-dependent kinase, two different Km values were apparent. The Km values for cyclic AMP-dependent kinase for either synthetic peptide were approximately 100 microM, but the Vmax for Arg-Lys-Arg-Ser32-Arg-Lys-Glu was 1.1 mumol/min/mg, while the Vmax for Arg-Lys-Glu-Ser36-Tyr-Ser-Val was 16.5 mumol/min/mg. These data suggest that although the two cyclic nucleotide-dependent protein kinases have similar substrate specificities, the determinants dictated by the primary sequence around the two phosphorylation sites in histone H2B are different for the two enzymes.     

Autophosphorylation of phosphorylase kinase. Divalent metal cation and nucleotide dependency

This study reports on the divalent metal ion specificity for phosphorylase kinase autophosphorylation and, in particular, provides a comparison between the efficacy of Mg2+ and Mn2+ in this role. As well as requiring Ca2+ plus divalent metal ion-ATP2- as substrate, both phosphorylase kinase autoactivation and phosphorylase conversion are additionally modulated by divalent cations. However, these reactions are affected differently by different ions. Phosphorylase kinase-catalyzed phosphorylase conversion is maximally enhanced by a 4- to 10-fold lower concentration of Mg2+ than is autocatalysis and, whereas both reactions are stimulated by Mg2+, autophosphorylation is activated by Mn2+, Co2+, and Ni2+ while phosphorylase a formation is inhibited. This difference may be due to an effect of free Mn2+ on phosphorylase rather than the inability of phosphorylase kinase to use MnATP as a substrate when catalyzing phosphorylase conversion since Mn2+, when added at a level which minimally decreases [MgATP], greatly inhibits phosphorylase phosphorylation. The interactions of Mn2+ with phosphorylase kinase are different from those of Mg2+. Not only are the effects of these ions on phosphorylase activation opposite, but they also provoke different patterns of subunit phosphorylation during phosphorylase kinase autocatalysis. With Mn2+, the time lag of phosphorylation of both the alpha and beta subunits of phosphorylase kinase in autocatalysis is diminished in comparison to what is observed with Mg2+, and the beta subunit is only phosphorylated to a maximum of 1 mol/mol of subunit. With both Mg2+ and Mn2+ the alpha subunit is phosphorylated to a level in excess of 3 mol/mol, a level similar to that obtained for beta subunit phosphorylation in the presence of Mg2+. The support of autophosphorylation by both Co2+ and Ni2+ has characteristics similar to those observed with Mn2+. Although Mn2+ stimulation of autophosphorylation occurs at levels much higher than normal physiological levels, the possible potential of phosphorylase kinase autophosphorylation as a control mechanism is illustrated by the 80- to 100-fold activation that occurs in the presence of Mn2+, a level far in excess of the enzyme activity change normally seen with covalent modification. Autophosphorylation of phosphorylase kinase demonstrates a Km for Mg X ATP2- of 27.7 microM and a Ka for Mg2+ of 3.1 mM. The reaction mechanism of autophosphorylation is intramolecular. This latter observation may indicate that phosphorylase kinase autocatalysis could be of potential physiological relevance and could occur with equal facility in cells containing either constitutively high or low levels of this enzyme.     

Cyclic AMP-dependent histone-specific nucleoplasmic protein kinase from rat liver.

A nucleoplasmic histone kinase activity was isolated from livers of adult rats and purified 39-fold compared with whole nuclei by ultracentrifugation of the nuclear extract and Sephadex G-200 gel filtration in the presence of cyclic AMP. Analysis by polyacrylamide-gel electrophoresis as well as by gel filtration indicates a mol.wt. of approx. 60,000 for the catalytic subunit and 130000-150000 for the cyclic AMP-binding activity. The purified enzyme displays a 20-fold greater preference for histone fractions 1 and 2b than for any non-histone substrate, including alpha-casein. Endogenous protein in the preparation is not appreciably phosphorylated. The unfractioned enzyme is stimulated significantly by cyclic GMP, cyclic IMP and dibutyryl cyclic AMP as well as by cyclic AMP. The catalytic reaction requires Mg2+ (Km 1.9mM) and ATP (Km 15.4 micron). Half-maximal activity of the enzyme is observed with histone 2b at 12micron and histone 1 at a higher substrate concentration. The pH optima are 6.1 and 6.5 with histones 2b and 1 respectively. This nuclear protein kinase appears to be distinct from other nuclear enzymes that have been reported, on the basis of histone specificity, univalent-salt-sensitivity, pH optima and nuclear location. However, the enzyme possesses many properties similar to those of the cytoplasmic kinases, including cyclic AMP-dependence, Mg2+ and ATP affinities and pH optima. It differs from cytoplasmic protein kinase type I, the major form in the liver, with respect to bivalent-cation effects and response to the heat-stable protein kinase inhibitor protein isolated from ox heart.     

The properties of purified low molecular weight phosphoprotein phosphatase from rabbit heart.

A simplified procedure for the purification of low molecular weight phosphoprotein phosphatase acting on muscle phosphorylase a has been described from rabbit heart. The enzyme was purified to homogeneity by acid precipitation, ethanol treatment, and chromatography on Sephadex G-75 and Sepharose-histone. The purified enzyme showed a single band when examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis; the molecular weight calculated by this method was 34 000. The S20, W value and Stokes radius for the enzyme was 3.35 and 24.0 A(1 A = 0.1 nm), respectively. Using these two values, a molecular weight of 35 000 was calculated. Purified enzyme showed a wide substrate specificity and catalyzed the dephosphorylation of phosphorylase a, glycogen synthase D, phosphorylated histone, and phosphorylated casein. Kinetic studies revealed the lowest Km with glycogen synthase D and maximum Vmax for the reaction with phosphorylase a.     

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.     

The control of phosphoprotein phosphatase by the second-site phosphorylation of a substrate. Studies with H2B histone as model substrate.

The phosphorylation of Ser-32, in addition to Ser-36 of H2B histone, stimulated the rate of Pi release from Ser-36 by the small form (Mr 31 000) of pig heart phosphoprotein phosphatase both in the absence and presence of 50 mM magnesium acetate. By phosphorylation at Ser-32, the Km value for Ser-36 phosphate in H2B histone was increased from 0.38 microM to 1.16 microM in the absence of magnesium acetate, but not significantly changed (from 37.4 microM to 26.2 microM) in the presence of magnesium acetate. With the large form (Mr 224000) of the phosphoprotein phosphatase, however, the phosphorylation at Ser-32 suppressed the rate of Pi release from Ser-36 both in the absence and presence of magnesium acetate. The Km value of the large form for Ser-36 phosphatase in H2B histone was nevertheless increased by phosphorylation at Ser-32, from 1.2 microM to 5.3 microM in the presence of magnesium acetate, but not changed (from 0.26 microM to 0.23 microM) in the absence of magnesium acetate.     

Purification and subunit structure of rat-liver phosphoprotein phosphatase, whose molecular weight is 260000 by gel filtration (phosphatase IB)

1. Phosphoprotein phosphatase IB is a form of rat liver phosphoprotein phosphatase, distinguished from the previously studied phosphoprotein phosphatase II [Tamura et al. (1980) Eur. J. Biochem. 104, 347-355] by earlier elution from DEAE-cellulose, by higher molecular weight on gel filtration (260000) and by lower activity toward phosphorylase alpha. This enzyme was purified to apparent homogeneity by chromatography on DEAE-cellulose, aminohexyl--Sepharose-4B, histone--Sepharose-4B, protamine--Sepharose-4B and Sephadex G-200. 2. The molecular weight of purified phosphatase IB was 260000 by gel filtration and 185000 from S20,W and Stokes' radius. Using histone phosphatase activity as the reference for comparison, the phosphorylase phosphatase activity of purified phosphatase IB was only one-fifth that of phosphatase II. 3. Sodium dodecyl sulfate gel electrophoresis revealed that phosphatase IB contains three types of subunit, namely alpha, beta and gamma, whose molecular weights are 35000, 69000 and 58000, respectively. The alpha subunit is identical to the alpha subunit of phosphatase II. While the beta subunit is also identical or similar to the beta subunit of phoshatase II, the gamma subunit appears to be unique to phosphatase IB. 4. When purified phosphatase IB was treated with 2-mercaptoethanol at -20 degrees C, the enzyme was dissociated to release the catalytically active alpha subunit. Along with this dissociation, there was a 7.4-fold increase in phosphorylase phosphatase activity; but histone phosphatase activity increased only 1.6-fold. The possible functions of the gamma subunit are discussed in relation to this activation of enzyme.     

Interaction of calmodulin with histones. Alteration of histone dephosphorylation

The Ca2+-dependent regulator protein (CDR), also frequently termed "calmodulin" was determined to influence the dephosphorylation of mixed calf thymus histones or purified histones 1, 2A, or 2B by a partially purified bovine brain phosphoprotein phosphatase. CDR increase the rate of dephosphorylation of mixed histones more than 20-fold. With increasing concentrations of mixed histones as substrate, a proportionate increase of CDR concentration was required to maintain maximal expression of histone phosphatase activity. Mixed histones suppressed the activation by CDR of a bovine brain cyclic nucleotide phosphodiesterase activity, with activation being restored by increased quantities of CDR. Dephosphorylation of casein and phosphorylase alpha by the phosphatase preparation was not affected by CDR. These observations support the interpretation that the effects of CDR on histone dephosphorylation are substrate-directed. The rates of dephosphorylation of histones 1, 2A, and 2B by the phosphatase were 4- to 12-fold more rapid at low (sub-micromolar) concentrations of free Ca2+ than at high (200 microM) Ca2+ in incubations containing CDR, but they were unaffected by Ca2+ in incubations without CDR. The addition of stoichiometric quantities of calmodulin increased the apparent Km of the phosphatase for the various histones 2- to 6-fold, while maximal velocities were 4- to 12-fold higher at low than at high added Ca2+. The inhibitory effect of Ca2+ on histone dephosphorylation was immediately reversible by chelation of Ca2+ with EDTA. Ca2+-dependent inhibition of histone 1 or 2B phosphatase activities was also produced by rabbit skeletal muscle troponin C, but not by rabbit skeletal muscle parvalbumin, by poly(L-aspartate) or poly(L-glutamate). The phosphorylated fragment from the NH2-terminal region of either H2A (generated by treatment with N-bromosuccinimide) or H2B (generated by treatment with cyanogen bromide) was dephosphorylated by the phosphatase, with the rates of dephosphorylation being reduced 3- to 6-fold by Ca2+ in incubations containing CDR.     

Control of protein phosphatase 2A by simian virus 40 small-t antigen.

Soluble, monomeric simian virus 40 (SV40) small-t antigen (small-t) was purified from bacteria and assayed for its ability to form complexes with protein phosphatase 2A (PP2A) and to modify its catalytic activity. Different forms of purified PP2A, composed of combinations of regulatory subunits (A and B) with a common catalytic subunit (C), were used. The forms used included free A and C subunits and AC and ABC complexes. Small-t associated with both the free A subunit and the AC form of PP2A, resulting in a shift in mobility during nondenaturing polyacrylamide gel electrophoresis. Small-t did not interact with the free C subunit or the ABC form. These data demonstrate that the primary interaction is between small-t and the A subunit and that the B subunit of PP2A blocks interaction of small-t with the AC form. The effect of small-t on phosphatase activity was determined by using several exogenous substrates, including myosin light chains phosphorylated by myosin light-chain kinase, myelin basic protein phosphorylated by microtubule-associated protein 2 kinase/ERK1, and histone H1 phosphorylated by protein kinase C. With the exception of histone H1, small-t inhibited the dephosphorylation of these substrates by the AC complex. With histone H1, a small stimulation of dephosphorylation by AC was observed. Small-t had no effect on the activities of free C or the ABC complex. A maximum of 50 to 75% inhibition was obtained, with half-maximal inhibition occurring at 10 to 20 nM small-t. The specific activity of the small-t/AC complex was similar to that of the ABC form of PP2A with myosin light chains or histone H1 as the substrate. These results suggested that small-t and the B subunit have similar qualitative and quantitative effects on PP2A enzyme activity. These data show that SV40 small-antigen binds to purified PP2A in vitro, through interaction with the A subunit, and that this interaction inhibits enzyme activity.     

The protein phosphatases involved in cellular regulation. 1. Modulation of protein phosphatases-1 and 2A by histone H1, protamine, polylysine and heparin

The phosphorylase phosphatases in rat and rabbit liver cytosol that are markedly stimulated by histone H1, protamine and polylysine were identified as protein phosphatases-2A0, 2A1 and 2A2 by anion-exchange chromatography, gel-filtration and immunotitration experiments. Histone H1 and protamine also stimulated the dephosphorylation of phosphorylase kinase, glycogen synthase, fructose-1,6-bisphosphatase, pyruvate kinase, acetyl-CoA carboxylase and phenylalanine hydroxylase by phosphatases-2A1 and 2A2, and with several of these substrates activation was even more striking (20-100-fold) than that observed with phosphorylase (approximately 5-fold). Activation by basic polypeptides did not involve dissociation of these phosphatases to the free catalytic subunit. The dephosphorylation of phosphorylase by protein phosphatase-1 was suppressed by basic polypeptides, protamine and polylysine being the most potent inhibitors. However, the dephosphorylation of glycogen synthase, pyruvate kinase and acetyl-CoA carboxylase were markedly stimulated by histone H1 and protamine (2-13-fold). Consequently, with the appropriate substrates, protein phosphatase-1 can also be regarded as a basic-polypeptide-activated protein phosphatase. Heparin stimulated (1.5-2-fold) the dephosphorylation of phosphorylase by phosphatases-2A0 and 2A1, provided that Mn2+ was present, but phosphatase-2A2 and the free catalytic subunit of phosphatase-2A were unaffected. Heparin, in conjunction with Mn2+, also stimulated (1.5-fold) the dephosphorylation of glycogen synthase (labelled in sites 3 abc), phosphorylase kinase and phenylalanine hydroxylase by phosphatase-2A1, but not by phosphatase-2A2. By contrast, the dephosphorylation of phosphorylase and phosphorylase kinase by protein phosphatase-1 was inhibited by heparin. However, dephosphorylation of glycogen synthase and pyruvate kinase by phosphatase-1 was stimulated by this mucopolysaccharide. The studies demonstrate that basic proteins can be used to distinguish protein phosphatase-1 from protein phosphatase-2A, but only if phosphorylase is employed as substrate. Optimal differentiation of the two phosphatases is observed at 30 micrograms/ml protamine or at heparin concentrations greater than 150 microM.     

Separation and characterization of two phosphorylase phosphatase inhibitors from rabbit skeletal muscle.

Two heat-stable and trypsin-labile inhibitors of phosphorylase phosphatase, designated inhibitor-1 and inhibitor-2, were partially purified from extracts of rabbit skeletal muscle by heating and coloumn chromatography using DEAE-dellulose and Bio-gel P-60. Inhibitor-1 exists in an active phosphorylated form and an inactive dephosphorylated form. The interconversion of phosphorylated inhibitor-1 and dephosphorylated inhibitor-1 is mediated by protein kinase dependent on adenosine 3':5'-monophosphate (cyclic AMP) and a Mn2+-stimulated phosphoprotein phosphatase. Inhibitory activity of inhibitor-2 is not influenced by treatment with either the kinase or the Mn2+-stimulated phosphatase. The molecular weights of inhibitor-1 and inhibitor-2 estimated by sodium dodecylsulfate-polyacrylamide gel electrophoresis are 26000 and 33000 respectively. Both inhibitor-1 and inhibitor-2 inhibit phosphorylase phosphatase by a mechanism which appears to be non-competitive with respect to the substrate phosphorylase a. Inhibitor fractions at early stages of purification also inhibit cyclic-AMP-dependent histone phosphorylation, but this kinase inhibitory activity resides with a protein moiety which is separable from inhibitor-1 and inhibitor-2.