Crystal structures of protein phosphatase-1 bound to motuporin and dihydromicrocystin-LA: elucidation of the mechanism of enzyme inhibition by cyanobacterial toxins

The microcystins and nodularins are tumour promoting hepatotoxins that are responsible for global adverse human health effects and wildlife fatalities in countries where drinking water supplies contain cyanobacteria. The toxins function by inhibiting broad specificity Ser/Thr protein phosphatases in the host cells, thereby disrupting signal transduction pathways. A previous crystal structure of a microcystin bound to the catalytic subunit of protein phosphatase-1 (PP-1c) showed distinct changes in the active site region when compared with protein phosphatase-1 structures bound to other toxins. We have elucidated the crystal structures of the cyanotoxins, motuporin (nodularin-V) and dihydromicrocystin-LA bound to human protein phosphatase-1c (gamma isoform). The atomic structures of these complexes reveal the structural basis for inhibition of protein phosphatases by these toxins. Comparisons of the structures of the cyanobacterial toxin:phosphatase complexes explain the biochemical mechanism by which microcystins but not nodularins permanently modify their protein phosphatase targets by covalent addition to an active site cysteine residue.     

Activation/dephosphorylation of muscle glycogen synthase phosphorylated by phosphorylase kinase

1. Glycogen synthase from rabbit skeletal muscle was phosphorylated by phosphorylase kinase to yield synthase b2. 2. Dephosphorylation and activation of synthase b2 by the catalytic subunits of protein phosphatase-1 (PP-1c) and protein phosphatase-2A (PP-2Ac) was studied. The apparent Km of PP-1c and PP-2Ac were 3.3 microM and 6.2 microM, respectively. The apparent Vmax of PP-1c was about two times larger than that of PP-2Ac. 3. Ligands with phosphate moiety (AMP, glucose-6-P at high concentration) caused an inhibition in dephosphorylation by both phosphatases. Spermine inhibited the dephosphorylation by PP-1c and stimulated the action of PP-2Ac. Therefore it can be employed to distinguish the phosphatases using synthase b2 as substrate.     

Differential regulation of protein phosphatase-1(I) by neurabin

Neurabin is a brain-specific actin and protein phosphatase-1 (PP-1) binding protein that inhibits the purified catalytic subunit of protein phosphatase-1 (PP-1(C)). However, endogenous PP-1 exists primarily as multimeric complexes of PP-1(C) bound to various regulatory proteins that determine its activity, substrate specificity, subcellular localization and function. The major form of endogenous PP-1 in brain is protein phosphatase-1(I) (PP-1(I)), a Mg(2+)/ATP-dependent form of PP-1 that consists of PP-1(C), the inhibitor-2 regulatory subunit, an activating protein kinase and other unidentified proteins. We have identified four PP-1(I) holoenzyme fractions (PP-1(IA), PP-1(IB), PP-1(IC), and PP-1(ID)) in freshly harvested pig brain separable by poly-L-lysine chromatography. Purified recombinant neurabin (amino acid residues 1-485) inhibited PP-1(IB) (IC(50)=1.1 microM), PP-1(IC) (IC(50)=0.1 microM), and PP-1(ID) (IC(50)=0.2 microM), but activated PP-1(IA) by up to threefold (EC(50)=40 nM). The PP-1(IA) activation domain was localized to neurabin(1-210). Our results indicate a novel mechanism of PP-1 regulation by neurabin as both an inhibitor and an activator of distinct forms of PP-1(I) in brain.     

Regulation of protein phosphatase-1G from rabbit skeletal muscle. 2. Catalytic subunit translocation is a mechanism for reversible inhibition of activity toward glycogen-bound substrates

The glycogen-associated form of protein phosphatase-1 (PP-1G) comprises a 37-kDa catalytic (C) subunit and a 161-kDa glycogen-binding (G) subunit. In the preceding paper in this issue of the journal we showed that the C subunit is released from PP-1G in response to phosphorylation of the G subunit by cAMP-dependent protein kinase. We now show that at 0.15-0.2 M KCl the phosphorylase phosphatase activity of glycogen-bound PP-1G is 5-8 times higher than that of released C subunit or unbound PP-1G, which are strongly inhibited at these ionic strengths. The activity of glycogen-bound PP-1G towards glycogen synthase was about 5-fold higher than that of released C subunit at 0.15M KCl. Studies with glycogen-bound substrates and myosin P-light chain (which does not interact with glycogen) indicated that PP-1G activity is only enhanced compared to free C subunit at near physiological ionic strength and when both PP-1G and substrate are glycogen-associated. The inhibition by increasing ionic strength and enhanced activity upon binding to glycogen reflected changes in K'm, but not Vmax. From the determined specificity constant, k'cat/K'm approximately 4 x 10(6) s-1 M-1, it was calculated that at physiological levels of glycogen-bound PP-1G (200 nM) and phosphorylase (70 microM), dephosphorylation of the latter could occur with a half time of 15 s, sufficient to account for inactivation rates in vivo. The much higher catalytic efficiency of glycogen-bound PP-1G toward the glycogen-metabolising enzymes at physiological ionic strength compared to free C subunit substantiates the role of PP-1G in the regulation of these substrates, and establishes a novel mechanism for selectively regulating their phosphorylation states in response to adrenalin and other factors affecting phosphorylation of the G subunit.     

Regulation of protein phosphatase-1G from rabbit skeletal muscle. 1. Phosphorylation by cAMP-dependent protein kinase at site 2 releases catalytic subunit from the glycogen-bound holoenzyme

The glycogen-associated form of protein phosphatase-1 (PP-1G) is a heterodimer comprising a 37-kDa catalytic (C) subunit and a 161-kDa glycogen-binding (G) subunit, the latter being phosphorylated by cAMP-dependent protein kinase at two serine residues (site 1 and site 2). Here the amino acid sequence surrounding site 2 has been determined and this phosphoserine shown to lie 19 residues C-terminal to site 1 in the primary structure. The sequence in this region is: (sequence; see text) At physiological ionic strength, phosphorylation of glycogen-bound PP-1G was found to release all the phosphatase activity from glycogen. The released activity was free C subunit, and not PP-1G, while the phospho-G subunit remained bound to glycogen. Dissociation reflected a greater than or equal to 4000-fold decrease in affinity of C subunit for G subunit and was readily reversed by dephosphorylation. Phosphorylation and dephosphorylation of site 2 was rate-limiting for dissociation and reassociation of C subunit. Release of C subunit was also induced by the binding of anti-site-1 Fab fragments to glycogen-bound PP-1G. At near physiological ionic strength, PP-1G and glycogen concentration, site 2 was autodephosphorylated by PP-1G with a t0.5 of 2.6 min at 30 degrees C, approximately 100-fold slower than the t0.5 for dephosphorylation of glycogen phosphorylase under the same conditions. Site 2 was a good substrate for all three type-2 phosphatases (2A, 2B and 2C) with t0.5 values less than those toward the alpha subunit of phosphorylase kinase. At the levels present in skeletal muscle, the type-2A and type-2B phosphatases are potentially capable of dephosphorylating site 2 in vivo within seconds. Site 1 was at least 10-fold less effective than site 2 as a substrate for all four phosphatases. In conjunction with information presented in the following paper in this issue of this journal, the results substantiate the hypothesis that PP-1 activity towards the glycogen-metabolising enzymes is regulated in vivo by reversible phosphorylation of a targetting subunit (G) that directs the C subunit to glycogen--protein particles. The efficient dephosphorylation of site 2 by the Ca2+/calmodulin-stimulated protein phosphatase (2B) provides a potential mechanism for regulating PP-1 activity in response to Ca2+, and represents an example of a protein phosphatase cascade.     

Effect of an Asp905Tyr mutation of the glycogen-associated regulatory subunit of protein phosphatase-1 on the regulation of glycogen synthesis by insulin and cyclic adenosine 3',5'-monophosphate agonists.

The glycogen-associated regulatory subunit of protein phosphatase-1 (PP-1G) plays a major role in insulin-stimulated glycogen synthesis and thus the regulation of nonoxidative glucose disposal in skeletal muscle. In a general population of Caucasians a polymorphism at codon 905 of PP-1G from an aspartate to tyrosine has been reported to be associated with insulin resistance and hypersecretion. In this report functional studies were performed on rat skeletal muscle L6 cells stably transfected with an Asp905Tyr mutant PP-1G to evaluate the impact of this mutation on cellular responsiveness to insulin and cAMP. Although transfection resulted in a 3-fold increase in mutant PP-1G subunit expression, basal and insulin-stimulated PP-1 catalytic activities were decreased when compared with L6 cells transfected with wild-type PP-1G. The Asp905Tyr mutation resulted in an increase in cellular sensitivity to cAMP agonist, resulting in an inhibition of insulin's stimulatory effect on glycogen synthesis. More importantly, low concentrations of (Bu)2cAMP completely reversed insulin's stimulatory effects on glycogen synthesis when added to insulin-treated cells expressing mutant PP-1G. This was due to a rapid activation of glycogen phosphorylase a and a simultaneous inactivation of glycogen synthase via cAMP-mediated reductions in insulin-stimulated PP-1 catalytic activities. We conclude that an Asp905Tyr mutation of PP-1G is accompanied by a relative increase in sensitivity to cAMP agonists as well as a diminished capacity of the mutant PP-1G to effectively mediate the inhibitory effects of insulin on glycogen breakdown via PP-1 activation.     

Crystal structure and mutagenesis of a protein phosphatase-1:calcineurin hybrid elucidate the role of the beta12-beta13 loop in inhibitor binding

Protein phosphatase-1 and protein phosphatase-2B (calcineurin) are eukaryotic serine/threonine phosphatases that share 40% sequence identity in their catalytic subunits. Despite the similarities in sequence, these phosphatases are widely divergent when it comes to inhibition by natural product toxins, such as microcystin-LR and okadaic acid. The most prominent region of non-conserved sequence between these phosphatases corresponds to the beta12-beta13 loop of protein phosphatase-1, and the L7 loop of toxin-resistant calcineurin. In the present study, mutagenesis of residues 273-277 of the beta12-beta13 loop of the protein phosphatase-1 catalytic subunit (PP-1c) to the corresponding residues in calcineurin (312-316), resulted in a chimeric mutant that showed a decrease in sensitivity to microcystin-LR, okadaic acid, and the endogenous PP-1c inhibitor protein inhibitor-2. A crystal structure of the chimeric mutant in complex with okadaic acid was determined to 2.0-A resolution. The beta12-beta13 loop region of the mutant superimposes closely with that of wild-type PP-1c bound to okadaic acid. Systematic mutation of each residue in the beta12-beta13 loop of PP-1c showed that a single amino acid change (C273L) was the most influential in mediating sensitivity of PP-1c to toxins. Taken together, these data indicate that it is an individual amino acid residue substitution and not a change in the overall beta12-beta13 loop conformation of protein phosphatase-1 that contributes to disrupting important interactions with inhibitors such as microcystin-LR and okadaic acid.     

Regulation of spinophilin Ser94 phosphorylation in neostriatal neurons involves both DARPP-32-dependent and independent pathways

Spinophilin is a protein phosphatase-1 (PP-1)- and actin-binding protein that is enriched in dendritic spines. Phosphorylation of the actin-binding domain of rat spinophilin at one or more sites by protein kinase A (PKA) inhibits actin binding. Here, we investigated the regulation of mouse spinophilin that contains only a single PKA-site (Ser94) within its actin-binding domain. In vitro phosphorylation of Ser94 resulted in the dissociation of spinophilin from actin filaments. In mouse neostriatal slices, phospho-Ser94 (p-Ser94) was dephosphorylated mainly by PP-1 and also by PP-2A. Activation of dopamine D1 receptors in striatonigral medium spiny neurons, and of adenosine A 2A receptors in striatopallidal medium spiny neurons increased, whereas activation of dopamine D2 receptors in striatopallidal neurons decreased, spinophilin Ser94 phosphorylation. In neostriatal slices from DARPP-32 (dopamine- and cAMP-regulated phosphoprotein of 32 kDa) knockout mice, the effects of D1, D2 and A 2A receptors were largely attenuated. Activation of NMDA receptors decreased Ser94 phosphorylation in a PP-2A-dependent, but DARPP-32-independent, manner. These results suggest that PKA-dependent phosphorylation of spinophilin at Ser94 in both striatonigral and striatopallidal neurons requires synergistic contributions from the PKA and DARPP-32/PP-1 pathways. In addition, PP-2A plays a role in Ser94 dephosphorylation in response to activation of both D2 and NMDA receptors.     

The role of autophosphorylation of cAMP-dependent protein kinase II in the inhibition of protein phosphatase-1

1. The inhibition of the catalytic subunit of protein phosphatase-1 (PP-1c) by the regulatory subunit of cAMP-dependent protein kinase II (RII) was studied. 2. Phosphorylation or thiophosphorylation of RII increased its inhibitory potency up to 4- and 6-fold and rendered it competitive with respect to the substrate of PP-1c, phosphorylase a. The Ki values for thiophospho-RII and phospho-RII were 200 and 500 nM, respectively. 3. Though PP-1c was able to release phosphate from phospho-RII, its activity once incubated with phospho-RII, remained inhibited even 80% of the phosphate was released from phospho-RII. 4. The catalytic subunit of cAMP-dependent protein kinase was effective in suspending the inhibition employed either before or after the addition of phospho-RII to PP-1c. 5. No exclusive bindings of thiophospho-RII and heat-stable protein inhibitors to the PP-1c could be proved by double inhibition studies, however some synergism was observed in their effect.     

Kinetics and the mechanism of interaction of the endoplasmic reticulum chaperone, calreticulin, with monoglucosylated (Glc1Man9GlcNAc2) substrate

Calreticulin is a lectin-like molecular chaperone of the endoplasmic reticulum in eukaryotes. Its interaction with N-glycosylated polypeptides is mediated by the glycan, Glc(1)Man(9)GlcNAc(2), present on the target glycoproteins. In this work, binding of monoglucosyl IgG (chicken) substrate to calreticulin has been studied using real time association kinetics of the interaction with the biosensor based on surface plasmon resonance (SPR). By SPR, accurate association and dissociation rate constants were determined, and these yielded a micromolar association constant. The nature of reaction was unaffected by immobilization of either of the reactants. The Scatchard analysis values for K(a) agreed well with the one obtained by the ratio k(1)/k(-1). The interaction was completely inhibited by free oligosaccharide, Glc(1)Man(9)GlcNAc(2,) whereas Man(9)GlcNAc(2) did not bind to the calreticulin-substrate complex, attesting to the exquisite specificity of this interaction. The binding of calreticulin to IgG was used for the development of immunoassay and the relative affinity of the lectin-substrate association was indirectly measured. The values are in agreement with those obtained with SPR. Although the reactions are several orders of magnitude slower than the diffusion controlled processes, the data are qualitatively and quantitatively consistent with single-step bimolecular association and dissociation reaction. Analyses of the activation parameters indicate that reaction is enthalpically driven and does not involve a highly ordered transition state. Based on these data, the mechanism of its chaperone activity is briefly discussed.     

Structure-based thermodynamic analysis of the dissociation of protein phosphatase-1 catalytic subunit and microcystin-LR docked complexes

The relationship between the structure of a free ligand in solution and the structure of its bound form in a complex is of great importance to the understanding of the energetics and mechanism of molecular recognition and complex formation. In this study, we use a structure-based thermodynamic approach to study the dissociation of the complex between the toxin microcystin-LR (MLR) and the catalytic domain of protein phosphatase-1 (PP-1c) for which the crystal structure of the complex is known. We have calculated the thermodynamic parameters (enthalpy, entropy, heat capacity, and free energy) for the dissociation of the complex from its X-ray structure and found the calculated dissociation constant (4.0 x 10(-11)) to be in excellent agreement with the reported inhibitory constant (3.9 x 10(-11)). We have also calculated the thermodynamic parameters for the dissociation of 47 PP-1c:MLR complexes generated by docking an ensemble of NMR solution structures of MLR onto the crystal structure of PP-1c. In general, we observe that the lower the root-mean-square deviation (RMSD) of the docked complex (compared to the X-ray complex) the closer its free energy of dissociation (deltaGd(o)) is to that calculated from the X-ray complex. On the other hand, we note a significant scatter between the deltaGd(o) and the RMSD of the docked complexes. We have identified a group of seven docked complexes with deltaGd(o) values very close to the one calculated from the X-ray complex but with significantly dissimilar structures. The analysis of the corresponding enthalpy and entropy of dissociation shows a compensation effect suggesting that MLR molecules with significant structural variability can bind PP-1c and that substantial conformational flexibility in the PP-1c:MLR complex may exist in solution.     

Transforming growth factor-beta (TGF-beta) binding to the extracellular domain of the type II TGF-beta receptor: receptor capture on a biosensor surface using a new coiled-coil capture system demonstrates that avidity contributes significantly to high affinity binding

Mature TGF-beta isoforms, which are covalent dimers, signal by binding to three types of cell surface receptors, the type I, II and III TGF-beta receptors. A complex composed of the TGF-beta ligand and the type I and II receptors is required for signaling. The type II receptor is responsible for recruiting TGF-beta into the heteromeric ligand/type I receptor/type II receptor complex. The purpose of this study was to test for the extent that avidity contributes to receptor affinity. Using a surface plasmon resonance (SPR)-based biosensor (the BIACORE), we captured the extracellular domain of the type II receptor (TbetaRIIED) at the biosensor surface in an oriented and stable manner by using a de novo designed coiled-coil (E/K coil) heterodimerizing system. We characterized the kinetics of binding of three TGF-beta isoforms to this immobilized TbetaRIIED. The results demonstrate that the stoichiometry of TGF-beta binding to TbetaRIIED was one dimeric ligand to two receptors. All three TGF-beta isoforms had rapid and similar association rates, but different dissociation rates, which resulted in the equilibrium dissociation constants being approximately 5pM for the TGF-beta1 and -beta3 isoforms, and 5nM for the TGF-beta2 isoform. Since these apparent affinities are at least four orders of magnitude higher than those determined when TGF-beta was immobilized, and are close to those determined for TbetaRII at the cell surface, we suggest that avidity contributes significantly to high affinity receptor binding both at the biosensor and cell surfaces. Finally, we demonstrated that the coiled-coil immobilization approach does not require the purification of the captured protein, making it an attractive tool for the rapid study of any protein-protein interaction.     

Kinetic modeling and determination of reaction constants of Alzheimer's beta-amyloid fibril extension and dissociation using surface plasmon resonance

To establish the kinetic model of the extension and dissociation of beta-amyloid fibrils (f(A)beta) in vitro, we analyzed these reactions using a surface plasmon resonance (SPR) biosensor. Sonicated f(A)beta were immobilized on the surface of the SPR sensor chip as seeds. The SPR signal increased linearly as a function of time after amyloid beta-peptides (Abeta) were injected into the f(A)beta-immobilized chips. The extension of f(A)beta was confirmed by atomic force microscopy. When flow cells were washed with running buffer, the SPR signal decreased with time after the extension reaction. The curve fitting resolved the dissociation reaction into the fast exponential and slow linear decay phases. Kinetic analysis of the effect of Abeta/f(A)beta concentrations on the reaction rate indicated that both the extension reaction and the slow linear phase of the dissociation were consistent with a first-order kinetic model; i.e., the extension/dissociation reactions proceed via consecutive association/dissociation of Abeta onto/from the end of existing fibrils. On the basis of this model, the critical monomer concentration ([M](e)) and the equilibrium association constant (K) were calculated, for the first time, to be 20 nM and 5 x 10(7) M(-1), respectively. Alternatively, [M](e) was directly measured as 200 nM, which may represent the equilibrium between the extension reaction and the fast phase of the dissociation. The SPR biosensor is a useful quantitative tool for the kinetic and thermodynamic study of the molecular mechanisms of f9A)beta formation in vitro.     

Modulation of type-1 protein phosphatase by synthetic peptides corresponding to the carboxyl terminus.

Protein phosphatase type-1 (PP-1) has a protease resistant catalytic core Mr = 35,000 (PP-35K) and carboxyl terminal segment which affects activity with various substrates. We found that micromolar concentration of a synthetic peptide, corresponding to residues 312-326 of the PP-1 carboxyl terminus (P312-326) that is missing from PP-35K, increased the phosphatase activity of PP-35K with phosphorylase and myosin light chains as substrates by decreasing the apparent Km without a change in Vm. Purified PP-1 and PP-35K were inhibited identically by okadaic acid, but peptide P312-326 only stimulated the activity of PP-35K, not full-length PP-1. Other peptides corresponding to the carboxyl terminus of phosphatase-2A or to the amino terminus of PP-1 did not affect the activity of PP-35K. A sequence conserved in PP-1 from different species, Pro-Ile-Thr-Pro-Pro was implicated as the active region because a derivative peptide, Ala-Pro-Ile-Thr-Pro-Pro-Ala, stimulated the activity of PP-35K to the same extent as peptide P312-326 although at higher concentrations. These results indicate that the carboxyl terminus of PP-1 interacts with the catalytic core to modulate its activity, and suggest that the physiological regulation of PP-1 may involve this segment.     

The glycogen-binding subunit of protein phosphatase-1G from rabbit skeletal muscle. Further characterisation of its structure and glycogen-binding properties

The glycogen-bound form of protein phosphatase-1 (PP-1G) was previously purified as a heterodimer composed of a 37-kDa catalytic (C) subunit and a proteolytically sensitive 103-kDa glycogen-binding (G) subunit [Str?hlfors, P., Hiraga, A. & Cohen, P. (1985) Eur. J. Biochem. 149, 295-303]. In this paper we demonstrate by a variety of criteria that the intact G subunit is a 161-kDa protein, and that the 103-kDa species (now termed G') is itself a product of proteolysis. A second phosphorylation site for cAMP-dependent protein kinase (termed site 2) was identified on the G subunit. The site 2 serine was phosphorylated at a comparable rate to site 1, and near stoichiometric phosphorylation could be achieved in the presence and absence of glycogen. Site 2 was dephosphorylated by PP-1 at a slow rate, whereas site 1 was resistant to autodephosphorylation. PP-1G, as well as the proteolytic activity responsible for degradation of the G subunit, remained tightly associated with glycogen-protein particles during washing with a variety of solvents. The PP-1G holoenzyme was released from glycogen-protein particles by dilution, with a dissociation half point corresponding to about 10 nM PP-1G. Binding experiments with purified PP-1G and glycogen indicated a bimolecular process with Kapp values corresponding to about 8 nM glycogen and 4 nM PP-1G. Binding was not significantly affected by increasing ionic strength to 0.5 M or variation of pH from 6 to 8. The results are consistent with a high-affinity glycogen-binding domain on the G subunit, and indicate that a physiological concentrations of phosphatase and glycogen, PP-1G should be almost entirely bound to glycogen.     

Molecular determinants of nuclear protein phosphatase-1 regulation by NIPP-1.

NIPP-1 is a subunit of the major nuclear protein phosphatase-1 (PP-1) in mammalian cells and potently inhibits PP-1 activity in vitro. Using yeast two-hybrid and co-sedimentation assays, we mapped a PP-1-binding site and the inhibition function to the central one-third domain of NIPP-1. Full-length NIPP-1 (351 residues) and the central domain, NIPP-1(143-217), were equally potent PP-1 inhibitors (IC50 = 0.3 nM). Synthetic peptides spanning the central domain of NIPP-1 further narrowed the PP-1 inhibitory function to residues 191-200. A second, noninhibitory PP-1-binding site was identified by far-Western assays with digoxygenin-conjugated catalytic subunit (PP-1C) and included a consensus RVXF motif (residues 200-203) found in many other PP-1-binding proteins. The substitutions, V201A and/or F203A, in the RVXF motif, or phosphorylation of Ser199 or Ser204, which are established phosphorylation sites for protein kinase A and protein kinase CK2, respectively, prevented PP-1C-binding by NIPP-1(191-210) in the far-Western assay. NIPP-1(191-210) competed for PP-1 inhibition by full-length NIPP-1(1-351), inhibitor-1 and inhibitor-2, and dissociated PP-1C from inhibitor-1- and NIPP-1(143-217)-Sepharose but not from full-length NIPP-1(1-351)-Sepharose. Together, these data identified some of the key elements in the central domain of NIPP-1 that regulate PP-1 activity and suggested that the flanking sequences stabilize the association of NIPP-1 with PP-1C.     

Studies of substrate-induced conformational changes in human cytomegalovirus protease using optical biosensor technology

The interaction between human cytomegalovirus (HCMV) protease and a peptide substrate was studied using a surface plasmon resonance (SPR)-based biosensor. Immobilization of the enzyme to the sensor chip surface by amine coupling resulted in an active enzyme with a higher catalytic efficiency than the enzyme in solution, primarily due to a lower K(m) value. The interaction between immobilized protease and substrate was characterized by a biphasic SPR signal. Rate constants for the formation of the initial enzyme-substrate complex could be determined from the sensorgrams. Simulated binding curves based on the determined k(cat) and the rate constants indicated that the complex binding signal did not originate from the accumulation of intermediates in the catalytic reaction. By chemical crosslinking of the immobilized HCMV protease, which was shown to limit the enzyme's structural flexibility, it was revealed that the obtained sensorgrams were composed of a signal caused by substrate binding and considerable structural alterations in the immobilized enzyme. Furthermore, HCMV protease was inactivated by chemical crosslinking, indicating that structural flexibility is essential for this enzyme. Parallel experiments with immobilized alpha-chymotrypsin revealed that it does not undergo similar conformational changes on peptide binding and that crosslinking did not inactivate the enzyme. The simultaneous detection of binding and conformational changes using optical biosensor technology is expected to be of importance for further characterization of the enzymatic properties of HCMV protease and for identification of inhibitors of this enzyme. It can also be of use for studies of other flexible proteins.     

Role of calcineurin and protein phosphatase-2A in the regulation of DARPP-32 dephosphorylation in neostriatal neurons

DARPP-32, a dopamine- and cyclic AMP-regulated phosphoprotein of Mr 32 kDa, is phosphorylated on Thr34 by cyclic AMP-dependent protein kinase, resulting in its conversion to a potent inhibitor of protein phosphatase-1 (PP-1). Conversely, Thr34-phosphorylated DARPP-32 is dephosphorylated and inactivated in vitro by calcineurin and protein phosphatase-2A (PP-2A). We have investigated the relative contributions of these protein phosphatases to the regulation of DARPP-32 dephosphorylation in mouse neostriatal slices. Cyclosporin A (5 microM), a calcineurin inhibitor, maximally increased the level of phosphorylated DARPP-32 by 17+/-2-fold. Okadaic acid (1 microM), an inhibitor of PP-1 and PP-2A, had a smaller effect, increasing phospho-DARPP-32 by 5.1+/-1.3-fold. The effect of okadaic acid on DARPP-32 phosphorylation was shown to be due to inhibition of PP-2A activity. Incubation of slices in the presence of cyclosporin A plus either okadaic acid or calyculin A, another PP-1/PP-2A inhibitor, caused a synergistic increase in the level of phosphorylated DARPP-32. The use of Ca2(+)-free/EGTA medium mimicked the effects of cyclosporin A on DARPP-32 phosphorylation, supporting the conclusion that the action of cyclosporin on DARPP-32 phosphorylation was attributable to blockade of the Ca2(+)-dependent activation of calcineurin. The results indicate that calcineurin and PP-2A, but not PP-1, act synergistically to maintain a low level of phosphorylated DARPP-32 in neostriatal slices.     

Suicide inhibition of canine myocardial cytosolic calcium-independent phospholipase A2. Mechanism-based discrimination between calcium-dependent and -independent phospholipases A2

The majority of phospholipase A2 activity in myocardium is calcium-independent and selective for hydrolysis of plasmalogen substrate (Wolf, R. A., and Gross, R. W. (1985) J. Biol. Chem. 260, 7295-7303; Hazen, S. L., Stuppy, R. J., and Gross, R. W. (1990) J. Biol. Chem. 265, 10622-10630). Accordingly, identification of an inhibitor which selectively targets calcium-independent phospholipases A2 would facilitate elucidation of the biologic significance of this class of intracellular phospholipases. We now report that the haloenol lactone, (E)-6-(bromomethylene)tetrahydro-3-(1-naphthalenyl)-2H-pyran-2-one (Compound 1), is a potent, irreversible, mechanism-based inhibitor of myocardial calcium-independent phospholipase A2 which is greater than 1000-fold specific for inhibition of myocardial calcium-independent phospholipase A2 in comparisons with multiple calcium-dependent phospholipases A2. Mechanism-based inhibition of myocardial cytosolic calcium-independent phospholipase A2 by Compound 1 was established by demonstrating: 1) time-dependent irreversible inactivation; 2) covalent binding of [3H]Compound 1 to the purified phospholipase A2; 3) ablation of covalent binding of [3H]Compound 1 after chemical inactivation of phospholipase A2 enzymic activity; 4) identical inhibition of myocardial phospholipase A2 by Compound 1 in the absence or presence of nucleophilic scavengers; 5) Compound 1 is a substrate for myocardial calcium-independent phospholipase A2 resulting in the generation of the electrophilic alpha-bromomethyl ketone; 6) phospholipase A2 inhibition requires the in situ generation of the reactive electrophile (i.e. neither the alpha-bromomethyl ketone nor the diproteoenol lactone analog are inhibitory); and 7) concomitant attenuation of the inhibitory potency and the extent of covalent adduct formation in the presence of saturating substrate. Collectively, these results demonstrate that the haloenol lactone, Compound 1, is a substrate for, covalently binds to, and irreversibly inhibits canine myocardial cytosolic calcium-independent phospholipase A2.