Detection and characterization of two ATP-dependent conformational changes in proteolytically inactive Escherichia coli Lon mutants by stopped flow kinetic techniques

Lon is an ATP dependent serine protease responsible for degrading denatured, oxidatively damaged and certain regulatory proteins in the cell. In this study we exploited the fluorescence properties of a dansylated peptide substrate (S4) and the intrinsic Trp residues in Lon to monitor peptide interacting with the enzyme. We generated two proteolytically inactive Lon mutants, S679A and S679W, where the active site serine is mutated to an Ala and Trp residue, respectively. Stopped-flow fluorescence spectroscopy was used to identify key enzyme intermediates generated along the reaction pathway prior to peptide hydrolysis. A two-step peptide binding event is detected in both mutants, where a conformational change occurs after a rapid equilibrium peptide binding step. The Kd for the initial peptide binding step determined by kinetic and equilibrium binding techniques is approximately 164 micromolar and 38 micromolar, respectively. The rate constants for the conformational change detected in the S679A and S679W Lon mutants are 0.74 +/- 0.10 s(-1) and 0.57 +/- 0.10 s(-1), respectively. These values are comparable to the lag rate constant determined for peptide hydrolysis (klag approximately 1 s(-1)) [Vineyard, D., et al. (2005) Biochemistry 45, 4602-4610]. Replacement of the active site Ser with Trp (S679W) allows for the detection of an ATP-dependent conformational change within the proteolytic site. The rate constant for this conformational change is 7.6 +/- 1.0 s(-1), and is essentially identical to the burst rate constant determined for ATP hydrolysis under comparable reaction conditions. Collectively, these kinetic data support a mechanism by which the binding of ATP to an allosteric site on Lon activates the proteolytic site. In this model, the energy derived from the binding of ATP minimally supports peptide cleavage by allowing peptide substrate access to the proteolytic site. However, the kinetics of peptide cleavage are enhanced by the hydrolysis of ATP.     

10-Formyltetrahydrofolate synthetase. Evidence for a conformational change in the enzyme upon binding of tetrahydropteroylpolyglutamates

The 10-formyltetrahydrofolate synthetase domain of the trifunctional enzyme C1-tetrahydrofolate synthase appears to undergo a conformational change in the presence of tetrahydropteroylpolyglutamates, MgATP, and ammonium ion. The binding of these ligands increases the denaturation temperature of the enzyme by 12 degrees C, abolishes the cold lability of the enzyme, and alters its susceptibility to digestion by chymotrypsin. The results suggest that a conformational change is dependent upon binding of the third glutamate residue of tetrahydropteroylpolyglutamates and the beta-phosphoryl group of MgATP. The Km values for MgATP and formate are lowered 3.6- and 520-fold, respectively, when tetrahydropteroyltriglutamate is used as the substrate in place of tetrahydropteroylmonoglutamate. A sensitive coupled assay involving C1-tetrahydrofolate synthase and serine hydroxymethyltransferase was developed to determine the activity of 10-formyltetrahydrofolate synthetase. The assay gives linear rates with the tetrahydropteroylpolyglutamates as substrates but not with the monoglutamate form.     

Interaction of peptide boronic acids with elastase: circular dichroism studies

Boronic acid derivatives of good peptide substrates of the serine proteases cause slow-binding inhibition, manifested as biphasic binding (Kettner and Shenvi: J. Biol Chem. 259:15106-15114, 1984). These inhibitors are thought to act as reaction-intermediate analogs. Three peptide boronic acids--Ac-Pro-boro-Val-OH, DNS-Ala-Pro-boro-Val-OH, and Ac-Ala-Ala-Pro-boro-Val-OH--were chosen for far-ultraviolet circular dichroism (CD) studies in order to determine whether the second phase involves a conformational change of pancreatic elastase. The dipeptide is a simple competitive inhibitor (Ki = 0.27 microM) and the latter are slow-binding inhibitors (Ki = 16.4 and 0.25 nM, respectively). Spectral deconvolution and correction for the formation of antiparallel beta-sheet by the peptide inhibitor itself indicate that there is no significant change in the secondary structure of the enzyme in either the initial or final inhibitor complex. A kinetic experiment confirmed that the slow-binding step was not associated with a CD spectral change, and that therefore a protein conformational change was not responsible for the slow binding.     

Studies of the mechanism of action and regulation of cAMP-dependent protein kinase

Magnetic resonance and kinetic studies of the catalytic subunit of a Type II cAMP-dependent protein kinase from bovine heart have established the active complex to be an enzyme-ATP-metal bridge. The metal ion is β,γ coordinated with Δ chirality at the β-phosphorous atom. The binding of a second metal ion at the active site which bridges the enzyme to the three phosphoryl groups of ATP, partially inhibits the reaction. Binding of the metal-ATP substrate to the enzyme occurs in a diffusion-controlled reaction followed by a 40 ° change in the glycosidic torsional angle. This conformational change results from strong interaction of the nucleotide base with the enzyme. NMR studies of four ATP-utilizing enzymes show a correlation between such conformational changes and high nucleotide base specificity. Heptapeptide substrates and substrate analogs bind to the active site of the catalytic subunit at a rate significantly lower than collision frequency indicating conformational selection by the enzyme or a subsequent slow conformational change. NMR studies of the conformation of the enzyme-bound peptide substrates have ruled out α-helical and β-pleated sheet structures. The results of kinetic studies of peptide substrates in which the amino acid sequence was systematically varied were used to rule out the obligatory requirement for all possible β-turn conformations within the heptapeptide although an enzymatic preference for a β_2–5 or β_3–6 turn could not be excluded. Hence if protein kinase has an absolute requirement for a specific secondary structure, then this structure must be a coil. In the enzyme-substrate complex the distance along the reaction coordinate between the γ-P of ATP and the serine oxygen of the peptide substrate (5.3 ± 0.7 Å) allows room for a metaphosphate intermediate. This finding together with kinetic observations as well as the location of the inhibitory metal suggest a dissociative mechanism for protein kinase, although a mechanism with some associative character remains possible. Regulation of protein kinase is accomplished by competition between the regulatory subunit and peptide or protein substrates at the active site of the catalytic subunit. Thus, the regulatory subunit is found by NMR to block the binding of the peptide substrate to the active site of protein kinase but allows the binding of the nucleotide substrate and divalent cations. The dissociation constant of the regulatory subunit from the active site (10^?10m) is increased ~10-fold by phosphorylation and ~10⁴-fold by the binding of cAMP, to a value (10^?5m) which exceeds the intracellular concentration of the R₂C₂ holoenzyme complex (10^?6m). The resulting dissociation of the holoenzyme releases the catalytic subunit, permitting the active site binding of peptide or protein substrates.     

Prediction of a ligand-induced conformational change in the catalytic core of Cdc25A

The cell cycle control phosphatases Cdc25 are dual specificity phosphatases that dephosphorylate both phosphothreonine and phosphotyrosine residues on their substrate proteins. The determination of the apo-protein structure of Cdc25A revealed that this enzyme has a completely different fold compared to all other phosphatases crystallised to date. The conformation of the active site residues does not seem very suitable for catalysis in this unliganded structure. We have studied some structural features of the Cdc25A apo-structure and a modelled Cdc25A-ligand complex by molecular dynamics simulations. The simulations predict a conformational change in the peptide backbone of the complex, which is not observed in the apo-structure. This ligand-induced conformational change yields a structure that is similar to other protein tyrosine phosphatase-ligand complexes that have been crystallised. The change in conformation takes place in the position between a serine and a glutamic acid residue in the phosphate binding loop. We suggest that this type of conformational change is an important molecular switch in the catalytic process.     

Studies on tyrosine residues in porcine muscle adenylate kinase. Circular dichroism spectra and chemical modification with tetranitromethane.

Substrate-induced conformational change of porcine muscle adenylate kinase (EC 2.7.4.3) is evidenced by a change in circular dichroism spectra in the near ultraviolet. In the absence of tryptophan in porcine muscle adenylate kinase, the spectral change may be assigned to a perturbation of tyrosine chromophore(s). The spectral change was specific for adenine nucleotide binding and was greater with ATP than with AMP. In the x-ray model, Tyr153 and Tyr154 are located at a hinge region of two domains which form a deep active site cleft and are therefore susceptible to conformational change on substrate binding. Adenylate kinase was treated with equimolar tetranitromethane. The yellow-colored product, separated from unmodified enzyme by substrate gradient elution on a phosphocellulose column, had about 1 mol of nitrotyrosine per mol of the enzyme by amino acid analysis and showed a slightly higher Km value than native enzyme for ADP (Km = 0.50 mM compared with 0.25 mM for native adenylate kinase). Spectrophotometric titration of nitroadenylate kinase gave pKa 8.4 for the dissociation constant of the nitrotyrosyl hydroxyl group. On binding ATP the pKa value increased to 9.0 while AMP binding caused very little change. By peptide mapping of the carboxypeptidase digestion product, 0.70 mol of nitro group per mol of adenylate kinase was detected on Tyr153 and a small amount of nitro group was also found on Tyr95. From these results it is proposed that Tyr153 is directly or indirectly involved in the binding of ATP.     

Conformational dynamics of threonine 195 and the S1 subsite in functional trypsin variants

Replacing the catalytic serine in trypsin with threonine (S195T variant) leads to a nearly complete loss of catalytic activity, which can be partially restored by eliminating the C42-C58 disulfide bond. The 0.69 μs of combined explicit solvent molecular dynamics (MD) simulations revealed continuous rearrangement of T195 with different conformational preferences between five trypsin variants tested. Among three conformational families observed for the T195 residue, one showed the T195 hydroxyl in a conformation analogous to that of the serine residue in wild-type trypsin, positioning the hydroxyl oxygen atom for attack on the carbonyl carbon of the peptide substrate. MD simulations demonstrated that this conformation was more populated for the C42A/C58V/S195T and C42A/C58A/S195T triple variants than for the catalytically inactive S195T variant and correlated with restored enzymatic activities for triple variants. In addition, observation of the increased motion of the S214-G219 segment in the S195T substituted variants suggested an existence of open and closed conformations for the substrate binding pocket. The closed conformation precludes access to the S1 binding site and could further reduce enzymatic activities for triple variants. Double variants with intact serine residues (C42A/C58A/S195 and C42A/C58V/S195) also showed interchange between closed and open conformations for the S214-G219 segment, but to a lesser extent than the triple variants. The increased conformational flexibility of the S1 subsite, which was not observed for the wild-type, correlated with reduced enzymatic activities and suggested a possible mode of substrate regulation for the trypsin variants tested.     

Direct calcium binding results in activation of brain serine racemase

Serine racemase (SR) is a brain enzyme present in glial cells, where it isomerizes L-serine into D-serine that, in turn, diffuses and coactivates the N-methyl-D-aspartate receptor through the binding to the so-called "glycine site." We have developed a method for the slow expression of SR in a eukaryotic vector that permits the correct insertion of the prosthetic group into the active site, rendering functional SR with a K(m) toward L-serine of 4.8 mm. Divalent cations such as calcium or manganese were necessary for complete enzyme activity, whereas the presence of chelators such as EDTA completely inhibited the enzyme. Moreover, direct binding of calcium to SR was evidenced using (45)Ca(2+). Gel filtration of the recombinant SR revealed the protein to be in a dimer-tetramer equilibrium. The addition of EDTA to a calcium-saturated serine racemase evokes a profound conformational change, as monitored by both fluorescence and circular dichroism techniques. Fluorescence titration allowed us to calculate a binding constant for calcium of 6.2 microm. Reagents that react with sulfhydryl groups, such as cystamine, were potent inhibitors of SR, in a clear reflection that one or more cysteine residues are important for enzyme activity. Additionally, 16 serine analogues were tested as a putative SR substrate or inhibitors. Significant inhibition was only observed for L-Ser-O-sulfate, L-cycloserine, and L-cysteine. Finally, activation of brain SR as a result of the changes in calcium concentration was studied in primary astrocytes. Treatment of astrocytes with the calcium ionophore, as well as with compounds that augment the intracellular calcium levels such as glutamate or kainate led to an increase in the amount of d-serine present in the extracellular medium. These results suggest that there might be a glutamatergic-mediated regulation of SR activity by intracellular calcium concentration.     

Rational scanning mutagenesis of a protein kinase identifies functional regions involved in catalysis and substrate interactions

A systematic mutagenesis strategy was used to identify the functional regions and residues of a protein kinase. Clusters of the charged amino acids in the catalytic subunit of Saccharomyces cerevisiae cAMP-dependent protein kinase, were systematically mutated to alanine, producing a set of mutations that encompassed the entire molecule. Residues indispensable for enzyme activity were identified by testing the ability of the mutants to function in vivo. Active mutants were assayed in vitro, and mutants with reduced specific activity were subsequently analyzed by steady-state kinetics to determine the effects of the mutation on kcat and on Km for MgATP and for a peptide substrate. Specific residues and regions of the enzyme were identified that are likely to be important in catalysis and in binding of MgATP, functions that are common to all protein kinases. Additional regions were identified that are likely to be important in binding a peptide substrate, the recognition of which is likely to be specific to the serine/threonine protein kinases that have a requirement for basic residues around the target hydroxyamino acid. The properties of mutants defective in substrate recognition were consistent with an ordered sequential reaction mechanism. This represents the first comprehensive analysis of a protein kinase by a rational mutagenesis strategy.     

Energetic and mechanistic studies of glucoamylase using molecular recognition of maltose OH groups coupled with site-directed mutagenesis

Molecular recognition using a series of deoxygenated maltose analogues was used to determine the substrate transition-state binding energy profiles of 10 single-residue mutants at the active site of glucoamylase from Aspergillus niger. The individual contribution of each substrate hydroxyl group to transition-state stabilization with the wild type and each mutant GA was determined from the relation Delta(DeltaG()) = -RT ln[(k(cat)/K(M))(x)/(k(cat)/K(M))(y)], where x represents either a mutant enzyme or substrate analogue and y the wild-type enzyme or parent substrate. The resulting binding energy profiles indicate that disrupting an active site hydrogen bond between enzyme and substrate, as identified in crystal structures, not only sharply reduces or eliminates the energy contributed from that particular hydrogen bond but also perturbs binding contributions from other substrate hydroxyl groups. Replacing the active site acidic groups, Asp55, Glu180, or Asp309, with the corresponding amides, and the neutral Trp178 with the basic Arg, all substantially reduced the binding energy contribution of the 4'- and 6'-OH groups of maltose at subsite -1, even though both Glu180 and Asp309 are localized at subsite 1. In contrast, the substitution, Asp176 --> Asn, located near subsites -1 and 1, did not substantially perturb any of the individual hydroxyl group binding energies. Similarly, the substitutions Tyr116 --> Ala, Ser119 --> Tyr, or Trp120 --> Phe also did not substantially alter the energy profiles even though Trp120 has a critical role in directing conformational changes necessary for activity. Since the mutations at Trp120 and Asp176 reduced k(cat) values by 50- and 12-fold, respectively, a large effect on k(cat) is not necessarily accompanied by changes in hydroxyl group binding energy contributions. Two substitutions, Asn182 --> Ala and Tyr306 --> Phe, had significant though small effects on interactions with 3- and 4'-OH, respectively. Binding interactions between the enzyme and the glucosyl group in subsite -1, particularly with the 4'- and 6'-OH groups, play an important role in substrate binding, while subsite 1 interactions may play a more important role in product release.     

Substrate binding to Src: A new perspective on tyrosine kinase substrate recognition from NMR and molecular dynamics

Most signal transduction pathways in humans are regulated by protein kinases through phosphorylation of their protein substrates. Typical eukaryotic protein kinases are of two major types: those that phosphorylate‐specific sequences containing tyrosine (~90 kinases) and those that phosphorylate either serine or threonine (~395 kinases). The highly conserved catalytic domain of protein kinases comprises a smaller N lobe and a larger C lobe separated by a cleft region lined by the activation loop. Prior studies find that protein tyrosine kinases recognize peptide substrates by binding the polypeptide chain along the C‐lobe on one side of the activation loop, while serine/threonine kinases bind their substrates in the cleft and on the side of the activation loop opposite to that of the tyrosine kinases. Substrate binding structural studies have been limited to four families of the tyrosine kinase group, and did not include Src tyrosine kinases. We examined peptide‐substrate binding to Src using paramagnetic‐relaxation‐enhancement NMR combined with molecular dynamics simulations. The results suggest Src tyrosine kinase can bind substrate positioning residues C‐terminal to the phosphoacceptor residue in an orientation similar to serine/threonine kinases, and unlike other tyrosine kinases. Mutagenesis corroborates this new perspective on tyrosine kinase substrate recognition. Rather than an evolutionary split between tyrosine and serine/threonine kinases, a change in substrate recognition may have occurred within the TK group of the human kinome. Protein tyrosine kinases have long been therapeutic targets, but many marketed drugs have deleterious off‐target effects. More accurate knowledge of substrate interactions of tyrosine kinases has the potential for improving drug selectivity.     

Correlation of an adenine-specific conformational change with the ATP-dependent peptidase activity of Escherichia coli Lon

Escherichia coli Lon, also known as protease La, is a serine protease that is activated by ATP and other purine or pyrimidine triphosphates. In this study, we examined the catalytic efficiency of peptide cleavage as well as intrinsic and peptide-stimulated nucleotide hydrolysis in the presence of hydrolyzable nucleoside triphosphates ATP, CTP, UTP, and GTP. We observed that the k(cat) of peptide cleavage decreases with the reduction in the nucleotide binding affinity of Lon in the following order: ATP > CTP > GTP approximately UTP. Compared to those of the other hydrolyzable nucleotide triphosphates, the ATPase activity of Lon is also the most sensitive to peptide stimulation. Collectively, our kinetic as well as tryptic digestion data suggest that both nucleotide binding and hydrolysis contribute to the peptidase turnover of Lon. The kinetic data that were obtained were further put into the context of the structural organization of Lon protease by probing the conformational change in Lon bound to the different nucleotides. Both adenine-containing nucleotides and CTP protect a 67 kDa fragment of Lon from tryptic digestion. Since this 67 kDa fragment contains the ATP binding pocket (also known as the alpha/beta domain), the substrate sensor and discriminatory (SSD) domain (also known as the alpha-helical domain), and the protease domain of Lon, we propose that the binding of ATP induces a conformational change in Lon that facilitates the coupling of nucleotide hydrolysis with peptide substrate delivery to the peptidase active site.     

Circular dichroism and fluorescence studies on the binding of ligands to the alpha subunit of tryptophan synthase.

Binding to the alpha subunit of tryptophan synthase induces extrinsic Cotton effects in the substrates indole (IND), indoleglycerol phosphate (IGP), and D-glyceraldehyde-3-P (D-GAP) and in the inhibitor indolepropanol phosphate (IPP). These effects disappear when the enzyme is denatured in guanidinium chloride. The induced circular dichroism (CD) was used to determine the dissociation constant and the number of binding sites for IPP. The dissociation constant so determined is equal to 48 muM and is in good agreement with the value of 48 muM obtained by equilibrium dialysis. From the temperature dependence of the dissociation constant, a value of -2.8 kcal/mol for the binding enthalpy was obtained. The determination of dissociation constants by means of extrinsic Cotton effects is shown to be quite feasible. CD competition experiments with glycerol phosphate (GP) suggest that IPP binds bifunctionally to the enzyme: via its indole part and its phosphate group. Indolepropanol, which lacks the phosphate group, does not show an extrinsic Cotton effect. Since the induced CD is strongly dependent on the binding geometry, the close similarity between the induced spectra in IPP and IGP is additional evidence that IPP is a good substrate analog. Binding to the enzyme results in a blue shift of the IPP fluorescence emission maximum. The dissociation constant determined by fluorescence titration equals 46 muM and agrees well with the values determined by the other two methods. Previous biochemical and fast kinetic studies suggested the existence of multiple conformational states for the enzyme and of ligand-induced conformational changes. No evidence was found in the far-uv CD spectra for conformational changes upon binding of IND and D-GAP. For IPP a very small effect was observed.     

The J-domain of Hsp40 couples ATP hydrolysis to substrate capture in Hsp70

The Escherichia coli Hsp40 DnaJ uses its J-domain to target substrate polypeptides for binding to the Hsp70 DnaK, but the mechanism of J-domain function has been obscured by a substrate-like interaction between DnaJ and DnaK. ATP hydrolysis in DnaK is associated with a conformational change that captures the substrate, and both DnaJ and substrate can stimulate ATP hydrolysis. However, substrates cannot trigger capture by DnaK in the presence of ATP, and substrates stimulate a DnaK conformational change that is uncoupled from ATP hydrolysis. The role of the J-domain was examined using the fluorescent derivative of a fusion protein composed of the J-domain and a DnaK-binding peptide. In the absence of ATP, DnaK-binding affinity of the fusion protein is similar to that of the unfused peptide. However, in the presence of ATP, the affinity of the fusion protein is dramatically increased, which is opposite to the decrease in DnaK affinity typically exhibited by peptides. Binding of a fusion protein that contains a defective J-domain is insensitive to ATP. According to results from isothermal titration calorimetry, the J-domain binds to the DnaK ATPase domain with weak affinity (K(D) = 23 microM at 20 degrees C). The interaction is characterized by a positive enthalpy, small heat capacity change (DeltaC(p)= -33 kcal mol(-1)), and increasing binding affinity for increasing temperatures in the physiological range. In conditions that support binding of the J-domain to the ATPase domain, the J-domain accelerates ATP hydrolysis and a simultaneous conformational change in DnaK that is associated with peptide capture. The defective J-domain is inactive, despite the fact that it binds to the DnaK ATPase domain with higher than wild-type affinity. The results are most consistent with an allosteric mechanism of J-domain action in which the J-domain couples ATP hydrolysis to peptide capture by accelerating ATP hydrolysis and delaying DnaK closure until ATP is hydrolyzed.     

Transient kinetic studies on the allosteric transition of phosphoglycerate dehydrogenase.

Stopped flow spectrophotometry was used to investigate the kinetics of the transition of the phosphoglycerate dehydrogenase (3-phosphoglycerate: NAD oxidoreductase, EC 1.1.1.95) reaction from the active to the inhibited rate upon the addition of the physiological inhibitor serine. The transition was characterized by a single first order rate constant (kobs,i) which was independent of enzyme concentration. At pH 8.5, kobs,i increased in a hyperbolic manner with serine concentration from 2 to 8 s-1. The increase in kobs,i occurred at serine concentrations where the steady state inhibition was virtually complete. These results indicate that serine inhibition is an allosteric process involving a conformational change in the enzyme. A model is presented in which serine at low concentrations binds exclusively to the inhibited state of the enzyme and shifts the equilibrium toward that state; at high serine concentrations, serine binds to the active state, facilitating its conversion to the inhibited state. An alternative model, which we favor, proposes two classes of inhibitor binding sites. The kinetics of the fluorescence quenching of enzyme-bound NADH by serine (Sugimoto, E., and Pizer, L.I. (1968) J. Biol. Chem. 243, 2090-2098), measured by stopped flow fluorimetry, was also characterized by a single first order rate constant (kobs,f.q.) which was independent of enzyme concentration. At pH 8.5, kobs,f.q. ranged from 0.4 s-1 at low serine concentrations to 1.1 s-1 at high serine concentrations. These results indicate that the fluorescence quenching induced by serine is a manifestation of a structural change in the enzyme. Enzyme and excess NADH were mixed with substrate and serine in the stopped flow instrument, and enzyme-bound NADH fluorescence was monitored by exciting through the protein at 285 nm. A rapid fluorescence quenching process, which occurred within the mixing time, was followed by a slower fluorescence enhancement process which terminated in a steady state level corresponding to the quenched fluorescence of the enzyme NADH serine complex. The rapid quenching was the result of substrate binding (Dubrow, R., and Pizer, L.I. (1977) J. Biol. Chem. 252, 1539-1551). The fluorescence enhancement was characterized by a single first order rate constant whose value for a given serine concentration corresponded with Kobs,j. This data shows that the quenched state of the enzyme-NADH-complex is the state which is directly responsible for the inhibition of enzyme activity. During catalysis the quenched state is achieved from a different initial conformation, and consequently at a different rate, than in the absence of substrate. kobs,j and kobs,f.q. were also measured using glycine, another inhibitor. The ultraviolet difference spectrum between enzyme and enzyme plus serine was determined and proposed to be the result of the same structural change which is responsible for the fluorescence quenching by serine.     

Mechanism of activation of cAMP-dependent protein kinase: in Mucor rouxii the apparent specific activity of the cAMP-activated holoenzyme is different than that of its free catalytic subunit

Kinetic constants for peptide phosphorylation by the catalytic subunit of the dimorphic fungus Mucor rouxii protein kinase A were determined using 13 peptides derived from the peptide containing the basic consensus sequence RRASVA, plus kemptide, S6 peptide, and protamine. As a whole, although with a greater Km, the order of preference of the peptides by the M. rouxii catalytic subunit was similar to the one displayed by mammalian protein kinase A. Particularly significant is the replacement of serine by threonine in the basic peptide RRATVA, which impaired its role as a substrate of M. rouxii catalytic subunit. Mucor rouxii protein kinase A is a good model in which to study the mechanism of activation since cAMP alone is not enough to promote activation and dissociation. Four peptides were selected for the study of holoenzyme activation under conditions in which the enzymatic activity was not proportional to the holoenzyme concentration: RRASVA, RRRRASVA, KRRRLSSRA (S6 peptide), and LRRASLG (kemptide); protamine was used as reference. Differential activation degree was observed depending on the peptide used and on cAMP concentration. Ratios of activity between different substrates displayed by the holoenzyme under the above conditions did not reflect the one expected for the free catalytic subunit. The degree of inhibition of the holoenzyme activity by an active peptide derived from the thermostable protein kinase inhibitor was dependent on the substrate used and on the holoenzyme concentration, while it was found to be independent of these two parameters for free catalytic subunit. Polycation modulation of holoenzyme activation by cAMP was also dependent on the polycation itself and on the peptide used as substrate. The observed kinetic differences between holoenzyme and free catalytic subunit were decreased or almost abolished when working at low enzyme or at high cAMP concentrations. Two hypotheses compatible with the results are discussed: substrate participation in the dissociation process and/or holoenzyme activation without dissociation.     

Conformational selection in the recognition of phosphorylated substrates by the catalytic domain of human Pin1

Post-translational phosphorylation and the related conformational changes in signaling proteins are responsible for regulating a wide range of subcellular processes. Human Pin1 is central to many of these cell signaling pathways in normal and aberrant subcellular processes, catalyzing cis-trans isomerization of the peptide ω-bond in phosphorylated serine/threonine-proline motifs in many proteins. Pin1 has therefore been identified as a possible drug target in many diseases, including cancer and Alzheimer's. The effects of phosphorylation on Pin1 substrates, and the atomistic basis for Pin1 recognition and catalysis, are not well understood. Here, we determine the conformational consequences of phosphorylation on Pin1 substrate analogues and the mechanism of recognition by the catalytic domain of Pin1 using all-atom molecular dynamics simulations. We show that phosphorylation induces backbone conformational changes on the peptide substrate analogues. We also show that Pin1 recognizes specific conformations of its substrate by conformational selection. Furthermore, dynamical correlated motions in the free Pin1 enzyme are present in the enzyme of the enzyme-substrate complex when the substrate is in the transition state configuration, suggesting that these motions play significant roles during catalytic turnover. These results provide a detailed atomistic picture of the mechanism of Pin1 recognition that can be exploited for drug design purposes and further our understanding of the synergistic complexities of post-translational phosphorylation and cis-trans isomerization.     

De-regulation of D-3-phosphoglycerate dehydrogenase by domain removal.

Escherichia coli 3-phosphoglycerate dehydrogenase (PGDH) catalyzes the first step in serine biosynthesis, and is allosterically inhibited by serine. Structural studies revealed a homotetramer in which the quaternary arrangement of subunits formed an elongated ellipsoid. Each subunit consisted of three domains: nucleotide, substrate and regulatory. In PGDH, extensive interactions are formed between nucleotide binding domains. A second subunit-subunit interaction occurs between regulatory domains creating an extended beta sheet. The serine-binding sites overlap this interface. In these studies, the nucleotide and substrate domains (NSDs) were subcloned to identify changes in both catalytic and physical properties upon removal of a subunit-subunit interface. The NSDs did not vary significantly from PGDH with respect to kinetic parameters with the exception that serine no longer had an effect on catalysis. Temperature dependent dynamic light scattering (DLS) revealed the NSDs aggregated > 5 degrees C before PGDH, indicating decreased stability. DLS and gel filtration studies showed that the truncated enzyme formed a tetramer. This result negated the hypothesis that the removal of the regulatory domain would create an enzyme mimic of the unregulated, closely related dimeric enzymes. Expression of the regulatory domain, to study conformational changes induced by serine binding, yielded a product that by CD spectra contained stable secondary structure. DLS and pulsed field gradient NMR studies of the regulatory domain showed the presence of higher oligomers instead of the predicted dimer. We have concluded that the removal of the regulatory domain is sufficient to eliminate serine inhibition but does not have the expected effect on the quaternary structure.     

Evidence that the substrate backbone conformation is critical to phosphorylation by p42 MAP kinase

The effect of prolyl bond isomers on the substrate recognition capabilities of various endoproteases may be investigated in a reaction where both cis/trans isomers co-exist. Here we address the question of whether enzyme reactions at the side chain of an amino acid preceding proline proceed through an isomer specific pathway. The proline-directed p42 mitogen-activated protein kinase (ERK2) was used to phosphorylate the serine side chain in Pro-Arg-Ser-Pro-Phe-4-nitroanilide under conditions where different amounts of cis prolyl isomer of the substrate were present. Initial phosphorylation rates were calculated ranging between zero at 100% cis isomer and around 60 pM/min at the equilibrium content of 83.5% trans isomer. In the presence of the peptidyl-prolyl cis/trans isomerase human hFKBP12 (500 nM), cis/trans isomerization proceeds rapidly, permitting the maximal phosphorylation rate to be observed in the dead time of the experiment. Results show that correct signature sequences are not sufficient to render potential substrates reactive to proline-directed enzymatic phosphorylations, but that the conformational state of the peptide bond following serine (threonine) is a critical determinant. Therefore, catalysis by peptidyl-prolyl cis/trans isomerases may add a new level of control to intracellular protein phosphorylations.