Anatomy of an energy-coupling mechanism--the interlocking catalytic cycles of the ATP sulfurylase-GTPase system

ATP sulfurylase, from Escherichia coli K-12, conformationally couples the rates and chemical potentials of the two reactions that it catalyzes, GTP hydrolysis and activated sulfate synthesis. The enzyme is rare among such coupling systems in that it links the potentials of small-molecule chemistries to one another, rather than to vectorial motion. The pre-steady-state stages of the catalytic cycle of ATP sulfurylase were studied using tools capable of distinguishing between enzyme-bound and solution-phase product for each of the four products of the enzyme. The study reveals that the two chemistries are linked at multiple points in the reaction coordinate. Linking begins with an isomerization prior to chemistry that initiates an ordered cleavage of the beta,gamma and alpha,beta bonds of GTP and ATP, respectively; the rates of these three sequential events increase successively, causing them to appear simultaneous. Linking is again seen in the late stages of the catalytic cycle: product release is ordered with P(i) departing prior to either GDP or PP(i). Release rate constants are determined for each product and used to construct a quantitative model of the mechanism that accurately predicts the behavior of this complex system.     

Isomerization couples chemistry in the ATP sulfurylase-GTPase system.

ATP sulfurylase catalyzes and couples the free energies of two reactions: GTP hydrolysis and the synthesis of activated sulfate, or APS. The GTPase active site undergoes changes during its catalytic cycle that are driven by events that occur at the APS-forming active site, which is located in a separate subunit. GTP responds to its changing environment by moving along its reaction path. The response, which may change the affinity or reactivity of GTP, can, in turn, produce alterations at the APS active site that drive APS synthesis. The resulting stepwise progression of the two reactions couples their free energies. The mechanism of ATP sulfurylase involves an enzyme isomerization that precedes and rate limits cleavage of the beta,gamma-bond of GTP. These fluorescence studies demonstrate that the isomerization is controlled by the binding of activators that drive ATP sulfurylase into forms that mimic different stages of the APS reaction. Only certain activators elicit the isomerization, suggesting that the APS reaction must proceed to a specific point in the catalytic cycle before the conformational "switch" that controls GTP hydrolysis is thrown. The isomerization is shown to require occupancy of the gamma-phosphate subsite of the GTP binding pocket. This requirement establishes that the isomerization results in a change in the interaction between the enzyme and the gamma-phosphate of GTP that emerges in the catalytic cycle during the transition from the nonisomerized to the isomerized E.GTP complex. The newly formed contact(s) appears to carry into the bond-breaking transition state, and to be essential for the enhanced affinity and reactivity of the nucleotide.     

ATP sulfurylase from Penicillium chrysogenum: measurements of the true specific activity of an enzyme subject to potent product inhibition and a reassessment of the kinetic mechanism

Homogeneous ATP sulfurylase from Penicillium chrysogenum has been reported to have an extremely low activity toward its physiological inorganic substrate, sulfate. This low activity is an artifact resulting from potent product inhibition by 5'-adenylylsulfate (APS) (Ki less than 0.25 microM). Assays based on 35S incorporation from 35SO4(2-) into charcoal-adsorbable [35S]APS are nonlinear with time, even in the presence of a large excess of inorganic pyrophosphatase. However, in the presence of excess APS kinase (along with excess pyrophosphatase), the ATP sulfurylase reaction is linear with time and the enzyme has a specific activity (Vmax) of 6 to 7 units mg protein-1 corresponding to an active site turnover number of at least 400 min-1. Monovalent oxyanions such as NO3-, ClO3-, ClO4-, and FSO3- are competitive with sulfate (or molybdate) and essentially uncompetitive with respect to MgATP. However, thiosulfate (SSO3(2-)), a true sulfate analog and dead-end inhibitor of the enzyme (competitive with sulfate or molybdate), exhibited clear noncompetitive inhibition against MgATP. Furthermore, APS was competitive with both MgATP and molybdate in the molybdolysis assay. These results suggest (a) that the mechanism of the normal forward reaction may be random rather than ordered and (b) that the monovalent oxyanions have a much greater affinity for the E X MgATP complex than for free E. In this respect, FSO3-, ClO4-, etc., are not true sulfate analogs although they might mimic an enzyme-bound species formed when MgATP is at the active site. The nonlinear ATP sulfurylase reaction progress curves (with APS accumulating in the presence of excess pyrophosphatase or PPi accumulating in the presence of excess APS kinase) were analyzed by means of "average velocity" plots based on an integrated rate equation. This new approach is useful for enzymes subject to potent product inhibition over a reaction time course in which the substrate concentrations do not change significantly. The analysis showed that ATP sulfurylase has an intrinsic specific activity of 6 to 7 units mg protein-1. Thus, the apparent stimulation of sulfurylase activity by APS kinase results from the continual removal of inhibitory APS rather than from an association of the two sulfate-activating enzymes to form a "3'-phospho-5'-adenylylsulfate synthetase" complex in which the sulfurylase has an increased catalytic activity. The progress curve analyses suggest that APS is competitive with both MgATP and sulfate, while MgPPi is a mixed-type inhibitor with respect to both substrates. The cumulative data point to a random sequence for the forward reaction with APS release being partially rate limiting.     

Energetics of S-adenosylmethionine synthetase catalysis

S-adenosylmethionine synthetase (ATP:L-methionine S-adenosyltransferase) catalyzes the only known route of biosynthesis of the primary biological alkylating agent. The internal thermodynamics of the Escherichia coli S-adenosylmethionine (AdoMet) synthetase catalyzed formation of AdoMet, pyrophosphate (PP(i)), and phosphate (P(i)) from ATP, methionine, and water have been determined by a combination of pre-steady-state kinetics, solvent isotope incorporation, and equilibrium binding measurements in conjunction with computer modeling. These studies provided the rate constants for substrate binding, the two chemical interconversion steps [AdoMet formation and subsequent tripolyphosphate (PPP(i)) hydrolysis], and product release. The data demonstrate the presence of a kinetically significant isomerization of the E.AdoMet.PP(i).P(i) complex before product release. The free energy profile for the enzyme-catalyzed reaction under physiological conditions has been constructed using these experimental values and in vivo concentrations of substrates and products. The free energy profile reveals that the AdoMet formation reaction, which has an equilibrium constant of 10(4), does not have well-balanced transition state and ground state energies. In contrast, the subsequent PPP(i) hydrolytic reaction is energetically better balanced. The thermodynamic profile indicates the use of binding energies for catalysis of AdoMet formation and the necessity for subsequent PPP(i) hydrolysis to allow enzyme turnover. Crystallographic studies have shown that a mobile protein loop gates access to the active site. The present kinetic studies indicate that this loop movement is rapid with respect to k(cat) and with respect to substrate binding at physiological concentrations. The uniformly slow binding rates of 10(4)-10(5) M(-)(1) s(-)(1) for ligands with different structures suggest that loop movement may be an intrinsic property of the protein rather than being ligand induced.     

Steady-state and pre-steady-state kinetic analysis of Mycobacterium tuberculosis pantothenate synthetase.

Pantothenate synthetase (EC 6.3.2.1), encoded by the panC gene, catalyzes the essential ATP-dependent condensation of D-pantoate and beta-alanine to form pantothenate in bacteria, yeast and plants. Pantothenate synthetase from Mycobacterium tuberculosis was expressed in E. coli, purified to homogeneity, and found to be a homodimer with a subunit molecular mass of 33 kDa. Initial velocity, product, and dead-end inhibition studies showed the kinetic mechanism of pantothenate synthetase to be Bi Uni Uni Bi Ping Pong, with ATP binding followed by D-pantoate binding, release of PP(i), binding of beta-alanine, followed by the release of pantothenate and AMP. Michaelis constants were 0.13, 0.8, and 2.6 mM for D-pantoate, beta-alanine, and ATP, respectively, and the turnover number, k(cat), was 3.4 s(-1). The formation of pantoyl adenylate, suggested as a key intermediate by the kinetic mechanism, was confirmed by (31)P NMR spectroscopy of [(18)O]AMP produced from (18)O transfer using [carboxyl-(18)O]pantoate. Single-turnover reactions for the formation of pyrophosphate and pantothenate were determined using rapid quench techniques, and indicated that the two half-reactions occurred with maximum rates of 1.3 +/- 0.3 and 2.6 +/- 0.3 s(-)(1), respectively, consistent with pantoyl adenylate being a kinetically competent intermediate in the pantothenate synthetase reaction. These data also suggest that both half-reactions are partially rate-limiting. Reverse isotope exchange of [(14)C]-beta-alanine into pantothenate in the presence of AMP was observed, indicating the reversible formation of the pantoyl adenylate intermediate from products.     

Catalytically important ionizations along the reaction pathway of yeast pyrophosphatase

Five catalytic functions of yeast inorganic pyrophosphatase were measured over wide pH ranges: steady-state PP(i) hydrolysis (pH 4. 8-10) and synthesis (6.3-9.3), phosphate-water oxygen exchange (pH 4. 8-9.3), equilibrium formation of enzyme-bound PP(i) (pH 4.8-9.3), and Mg(2+) binding (pH 5.5-9.3). These data confirmed that enzyme-PP(i) intermediate undergoes isomerization in the reaction cycle and allowed estimation of the microscopic rate constant for chemical bond breakage and the macroscopic rate constant for PP(i) release. The isomerization was found to decrease the pK(a) of the essential group in the enzyme-PP(i) intermediate, presumably nucleophilic water, from >7 to 5.85. Protonation of the isomerized enzyme-PP(i) intermediate decelerates PP(i) hydrolysis but accelerates PP(i) release by affecting the back isomerization. The binding of two Mg(2+) ions to free enzyme requires about five basic groups with a mean pK(a) of 6.3. An acidic group with a pK(a) approximately 9 is modulatory in PP(i) hydrolysis and metal ion binding, suggesting that this group maintains overall enzyme structure rather than being directly involved in catalysis.     

Gastric H/K-ATPase liberates two moles of Pi from one mole of phosphoenzyme formed from a high-affinity ATP binding site and one mole of enzyme-bound ATP at the low-affinity site during cross-talk between catalytic subunits

The maximum amount of acid-stable phosphoenzyme (E32P)/mol of alpha chain of pig gastric H/K-ATPase from [gamma-32P]ATP (K(1/2) = 0.5 microM) was found to be approximately 0.5, which was half of that formed from 32P(i) (K(1/2) = 0.22 mM). The maximum 32P binding for the enzyme during turnover in the presence of [gamma-32P]ATP or [alpha-32P]ATP was due to 0.5 mol of E32P + 0.5 mol of an acid-labile enzyme-bound [gamma-32P]ATP (EATP) or 0.5 mol of an acid-labile enzyme-bound [alpha-32P]ATP, respectively. The K(1/2) for EATP formation in both cases was 0.12 approximately 0.14 mM. The turnover number of the enzyme (i.e., the H+-ATPase activity/(EP + EATP)) was very close to the apparent rate constants for EP breakdown and P(i) liberation, both of which decreased with increasing concentrations of ATP. The ratio of the amount of P(i) liberated to that of EP that disappeared increased from 1 to approximately 2 with increasing concentrations of ATP (i.e., equal amounts of EP and EATP exist, both of which release phosphate in the presence of high concentrations of ATP). This represents the first direct evidence, for the case of a P-type ATPase, in which 2 mol of P(i) liberation occurs simultaneously from 1 mol of EP for half of the enzyme molecules and 1 mol of EATP for the other half during ATP hydrolysis. Each catalytic alpha chain is involved in cross-talk, thus maintaining half-site phosphorylation and half-site ATP binding which are induced by high- and low-affinity ATP binding, respectively, in the presence of Mg2+.     

Properties and mechanism of action of pyruvate, phosphate dikinase from leaves

1. Sugar-cane leaf pyruvate,P(i) dikinase was prepared free of enzymes that would interfere with studies on the stoicheiometry and mechanism of the reaction it catalyses. The reaction was unequivocally shown to involve the conversion of equimolar amounts of pyruvate, ATP and P(i) into phosphoenolpyruvate, AMP and PP(i). 2. The purified enzyme was stable at pH8.3 only if stored at about 20 degrees in the presence of Mg(2+) and a thiol-reducing reagent, care being taken to prevent the oxidation of the thiol. 3. The apparent Michaelis constants for phosphoenolpyruvate and PP(i) were 0.11mm and 0.04mm respectively and that for AMP was less than 4mum. 4. At pH8.3 the initial velocity of the reaction was about 6 times as fast in the direction towards phosphoenolpyruvate synthesis as in the reverse direction. 5. With the exception of ATP, all the products of the reaction in both directions were inhibitory. 6. The phosphate groups of PP(i) were derived from P(i) and from the terminal phosphate of ATP. 7. Isotope-exchange studies indicated that the reaction proceeds in the following steps:Enzyme+ATP+P(i) right harpoon over left harpoon Enzyme-P+AMP+PP(i)Enzyme-P+pyruvate right harpoon over left harpoon Enzyme+phosphoenolpyruvate     

Tublin: nucleotide binding and enzymic activity

The existence of two distinguishable guanine nucleotide binding sites per molecule of tubulin has been confirmed. One site rapidly exchanges GTP with the medium (E site), the other site binds GDP or GTP very strongly (N site). The GDP bound to the N site can be converted to GTP by transphosphorylase activity using GTP or ATP as the phosphate donor. ATP binds only weakly to the E site, yet it is a better substrate than GTP in the transphosphorylation reaction. The nucleotide used in this reaction therefore comes from the medium and binds to a third site on tubulin itself or to another protein associated with it. Tubulin preparations also show a low ATPase or GTPase activity, which in part is accounted for by turnover of GTP on the N site, the remainder may be associated with the transphosphorylase, tubulin aggregation or contaminating enzyme activity. In addition, during microtubule formation the bound γ-³²P of GTP is lost from both the E and the N sites, leaving bound GDP on the former and probably on the latter site.     

Structural characterization of adenine nucleotides bound to Escherichia coli adenylate kinase. 2. 31P and 13C relaxation measurements in the presence of cobalt(II) and manganese(II)

13C spin-lattice relaxation rates have been measured for two complexes of Escherichia coli adenylate kinase (AKe), viz., AKe. [U-(13)C]ATP and AKe.[U-(13)C]AMP.GDP in the presence of the substituent activating paramagnetic cation Mn(II) for the purpose of determination of the enzyme-bound conformations of ATP and AMP. (GDP has been added to the AMP complex with the enzyme in order to hold the cation in the bound complex.) Measurements of relaxation times at three different (13)C frequencies, 181.0, 125.7, and 75.4 MHz, indicate that the relaxation times in the enzyme-nucleotide complexes with the paramagnetic cation are not exchange-limited; i.e. , they are larger than the effective lifetimes of cation binding to these complexes and are, therefore, dependent on the cation-(13)C distances. An analysis of the frequency-dependent relaxation data allowed all of the ten Mn(II)-(13)C distances to be determined in each of the complexes. Similar measurements of the (31)P relaxation rate made on AKe.ATP and AKe.AMP.GDP complexes in the presence of Co(II) as the activating cation yielded Co(II)-(31)P distances for each adenine nucleotide. These distances, together with the interproton distances determined previously from TRNOESY experiments [Lin, Y., and Nageswara Rao, B. D. (2000) Biochemistry 39, 3636-3646], led to a complete characterization of both ATP and AMP conformations in AKe-bound complexes. These conformations differ significantly from the nucleotide conformations in crystals of AKe. AP(5)A and AKe.AMP.AMPPNP as determined by X-ray crystallography.     

Characterization and properties of the pyruvate phosphorylation system of Acetobacter xylinum

The enzyme responsible for the direct phosphorylation of pyruvate during gluconeogenesis in Acetobacter xylinum has been purified 46-fold from ultrasonic extracts and freed from interfering enzyme activities. The enzyme was shown to catalyze the reversible Mg(2+) ion-dependent conversion of equimolar amounts of pyruvate, adenosine triphosphate (ATP), and orthophosphate (P(i)) into phosphoenolpyruvate (PEP), adenosine monophosphate (AMP), and pyrophosphate (PP). The optimal pH for PEP synthesis was pH 8.2; for the reversal it was pH 6.5. The ratio between the initial rates of the reaction in the forward and reverse directions was 5.1 at pH 8.2 and 0.45 at pH 6.5. The apparent K(m) values of the components of the system in the forward reaction were: pyruvate, 0.2 mm; ATP, 0.4 mm; P(i), 0.8 mm; Mg(2+), 2.2 mm; and for the reverse reaction: PEP, 0.1 mm; AMP, 1.6 mum; PP, 0.067 mm; Mg(2+), 0.87 mm. PEP formation was inhibited by AMP and PP. The inhibition by AMP was competitive with regard to ATP (K(i) = 0.2 mm). The reverse reaction was inhibited competitively by ATP and noncompetitively by pyruvate. The enzyme was strongly inhibited by p-hydroxymercuribenzoate. The inhibition was reversed by dithiothreitol and glutathione. The properties of the enzyme are discussed in relation to the regulation of the opposing enzymatic activities involved in the interconversion of PEP and pyruvate in A. xylinum.     

Kinetic mechanism and metabolic role of pyruvate phosphate dikinase from Entamoeba histolytica

The kinetic mechanism and the metabolic role of pyruvate phosphate dikinase from Entamoeba histolytica were investigated. The initial velocity patterns in double reciprocal plots were parallel for the phosphoenolpyruvate/AMP and phosphoenolpyruvate/pyrophosphate substrate pairs and intersecting for the AMP/pyrophosphate pair. This suggests a kinetic mechanism with two independent reactions. The rate of ATP synthesis at saturating and equimolar concentrations of phosphoenolpyruvate, AMP, and pyrophosphate was inhibited by phosphate, which is consistent with an ordered steady-state mechanism. Enzyme phosphorylation by [(32)P(i)]pyrophosphate depends on the formation of a ternary complex between AMP, pyrophosphate, and pyruvate phosphate dikinase. In consequence, the reaction that involves the AMP/pyrophosphate pair follows a sequential steady-state mechanism. The product inhibition patterns of ATP and phosphate versus phosphoenolpyruvate were noncompetitive and uncompetitive, respectively, suggesting that these products were released in an ordered process (phosphate before ATP). The ordered release of phosphate and ATP and the noncompetitive inhibition patterns of pyruvate versus AMP and versus pyrophosphate also supported the sequential kinetic mechanism between AMP and pyrophosphate. Taken together, our data provide evidence for a uni uni bi bi pingpong mechanism for recombinant pyruvate phosphate dikinase from E. histolytica. The Delta G value for the reaction catalyzed by pyruvate phosphate dikinase (+2.7 kcal/mol) determined under near physiological conditions indicates that the synthesis of ATP is not thermodynamically favorable in trophozoites of E. histolytica.     

Kinetic and stability properties of Penicillium chrysogenum ATP sulfurylase missing the C-terminal regulatory domain

ATP sulfurylase from Penicillium chrysogenum is a homohexameric enzyme that is subject to allosteric inhibition by 3'-phosphoadenosine 5'-phosphosulfate. In contrast to the wild type enzyme, recombinant ATP sulfurylase lacking the C-terminal allosteric domain was monomeric and noncooperative. All kcat values were decreased (the adenosine 5'-phosphosulfate (adenylylsulfate) (APS) synthesis reaction to 17% of the wild type value). Additionally, the Michaelis constants for MgATP and sulfate (or molybdate), the dissociation constant of E.APS, and the monovalent oxyanion dissociation constants of dead end E.MgATP.oxyanion complexes were all increased. APS release (the k6 step) was rate-limiting in the wild type enzyme. Without the C-terminal domain, the composite k5 step (isomerization of the central complex and MgPPi release) became rate-limiting. The cumulative results indicate that besides (a) serving as a receptor for the allosteric inhibitor, the C-terminal domain (b) stabilizes the hexameric structure and indirectly, individual subunits. Additionally, (c) the domain interacts with and perfects the catalytic site such that one or more steps following the formation of the binary E.MgATP and E.SO4(2-) complexes and preceding the release of MgPPi are optimized. The more negative entropy of activation of the truncated enzyme for APS synthesis is consistent with a role of the C-terminal domain in promoting the effective orientation of MgATP and sulfate at the active site.     

Investigation of the catalytic site within the ATP-grasp domain of Clostridium symbiosum pyruvate phosphate dikinase

Pyruvate phosphate dikinase (PPDK) catalyzes the interconversion of ATP, P(i), and pyruvate with AMP, PP(i), and phosphoenolpyruvate (PEP) in three partial reactions as follows: 1) E-His + ATP --> E-His-PP.AMP; 2) E-His-PP.AMP + P(i) --> E-His-P.AMP.PP(i); and 3) E-His-P + pyruvate --> E.PEP using His-455 as the carrier of the transferred phosphoryl groups. The crystal structure of the Clostridium symbiosum PPDK (in the unbound state) reveals a three-domain structure consisting of consecutive N-terminal, central His-455, and C-terminal domains. The N-terminal and central His-455 domains catalyze partial reactions 1 and 2, whereas the C-terminal and central His-455 domains catalyze partial reaction 3. Attempts to obtain a crystal structure of the enzyme with substrate ligands bound at the nucleotide binding domain have been unsuccessful. The object of the present study is to demonstrate Mg(II) activation of catalysis at the ATP/P(i) active site, to identify the residues at the ATP/P(i) active site that contribute to catalysis, and to identify roles for these residues based on their positions within the active site scaffold. First, Mg(II) activation studies of catalysis of E + ATP + P(i) --> E-P + AMP + PP(i) partial reaction were carried out using a truncation mutant (Tem533) in which the C-terminal domain is absent. The kinetics show that a minimum of 2 Mg(II) per active site is required for the reaction. The active site residues used for substrate/cofactor binding/activation were identified by site-directed mutagenesis. Lys-22, Arg-92, Asp-321, Glu-323, and Gln-335 mutants were found to be inactive; Arg-337, Glu-279, Asp-280, and Arg-135 mutants were partially active; and Thr-253 and Gln-240 mutants were almost fully active. The participation of the nucleotide ribose 2'-OH and alpha-P in enzyme binding is indicated by the loss of productive binding seen with substrate analogs modified at these positions. The ATP, P(i), and Mg(II) ions were docked into the PPDK N-terminal domain crevice, in an orientation consistent with substrate/cofactor binding modes observed for other members of the ATP-Grasp fold enzyme superfamily and consistent with the structure-function data. On the basis of this docking model, the ATP polyphosphate moiety is oriented/activated for pyrophosphoryl transfer through interaction with Lys-22 (gamma-P), Arg-92 (alpha-P), and the Gly-101 to Met-103 loop (gamma-P) as well as with the Mg(II) cofactors. The P(i) is oriented/activated for partial reaction 2 through interaction with Arg-337 and a Mg(II) cofactor. The Mg(II) ions are bound through interaction with Asp-321, Glu-323, and Gln-335 and substrate. Residues Glu-279, Asp-280, and Arg-135 are suggested to function in the closure of an active site loop, over the nucleotide ribose-binding site.     

Investigation of the role of the domain linkers in separate site catalysis by Clostridium symbiosum pyruvate phosphate dikinase.

Pyruvate phosphate dikinase (PPDK) catalyzes the reversible reaction: ATP + P(i) + pyruvate <--> AMP + PP(i) + PEP using Mg2+ and NH4+ ions as cofactors. The reaction takes place in three steps, each mediated by a carrier histidine residue located on the surface of the central domain of this three-domain enzyme: (1) E-His + ATP <--> E-His-PP.AMP, (2) E-His-PP.AMP + P(i) <--> E-His-P + AMP + PP(i), (3) E-His-P + pyruvate <--> E-His + PEP. The first two partial reactions are catalyzed at an active site located on the N-terminal domain, and the third partial reaction is catalyzed at an active site located on the C-terminal domain. For catalytic turnover, the central domain travels from one terminal domain to the other. The goal of this work is to determine whether the two connecting linkers direct the movement of the central domain between active sites during catalytic turnover. The X-ray crystal structure of the enzyme suggests interaction between the two linkers that may result in their coordinated movement. Mutations were made at the linkers for the purpose of disrupting the linker-linker interaction and, hence, synchronized linker movement. Five linker mutants were analyzed. Two of these contain 4-Ala insertions within the solvated region of the linker, and three have 3-residue deletions in this region. The efficiencies of the mutants for catalysis of the complete reaction as well as the E-His + ATP <--> E-His-PP.AMP partial reaction at the N-terminal domain and the E-His + PEP <--> E-His-P + pyruvate reaction at the C-terminal domain were measured to assess linker function. Three linker mutants are highly active catalysts at both active sites, and the fourth is highly active at one site but not the other. These results are interpreted as evidence against coordinated linker movement, and suggest instead that the linkers move independently as the central domain travels between active sites. It is hypothesized that while the linkers play a passive role in central domain-terminal domain docking, their structural design minimizes the conformational space searched in the diffusion process.     

Variant of human enzyme sequesters reactive intermediate

In cellular environments, coupled hydrolytic reactions are used to force efficient product formation in enzyme-catalyzed reactions. In the first step of protein synthesis, aminoacyl-tRNA synthetases react with amino acid and ATP to form an enzyme-bound adenylate that, in the next step, reacts with tRNA to form aminoacyl-tRNA. The reaction liberates pyrophosphate (PP(i)) which, in turn, can be hydrolyzed by pyrophosphatase to drive efficient aminoacylation. A potential polymorphic variant of human tryptophanyl-tRNA synthetase is shown here to sequester tryptophanyl adenylate. The bound adenylate does not react efficiently with the liberated PP(i) that normally competes with tRNA to resynthesize ATP and free amino acid. Structural analysis of this variant showed that residues needed for binding ATP phosphates and thus PP(i) were reoriented from their conformations in the structure of the more common sequence variant. Significantly, the reorientation does not affect reaction with tRNA, so that efficient aminoacylation is achieved.     

Structural and functional analysis of a truncated form of Saccharomyces cerevisiae ATP sulfurylase: C-terminal domain essential for oligomer formation but not for activity

ATP sulfurylase catalyzes the first step in the activation of sulfate by transferring the adenylyl-moiety (AMP approximately ) of ATP to sulfate to form adenosine 5'-phosphosulfate (APS) and pyrophosphate (PP(i)). Subsequently, APS kinase mediates transfer of the gamma-phosphoryl group of ATP to APS to form 3'-phosphoadenosine 5'-phosphosulfate (PAPS) and ADP. The recently determined crystal structure of yeast ATP sulfurylase suggests that its C-terminal domain is structurally quite independent from the other domains, and not essential for catalytic activity. It seems, however, to dictate the oligomerization state of the protein. Here we show that truncation of this domain results in a monomeric enzyme with slightly enhanced catalytic efficiency. Structural alignment of the C-terminal domain indicated that it is extremely similar in its fold to APS kinase although not catalytically competent. While carrying out these structural and functional studies a surface groove was noted. Careful inspection and modeling revealed that the groove is sufficiently deep and wide, as well as properly positioned, to act as a substrate channel between the ATP sulfurylase and APS kinase-like domains of the enzyme.     

Formation and utilization of formyl phosphate by N10-formyltetrahydrofolate synthetase: evidence for formyl phosphate as an intermediate in the reaction

N10-Formyltetrahydrofolate synthetase from bacteria and yeast catalyzes a slow formate-dependent ADP formation in the absence of H4folate. The synthesis of formyl phosphate by the enzyme was detected by trapping the intermediate as formyl hydroxamate. That the "formate kinase" activity was part of the catalytic center of N10-formyltetrahydrofolate synthetase was shown by demonstrating coordinate inactivation of the "kinase" and synthetase activities by heat and a sulfhydryl reagent, similar effects of monovalent cations, similar Km values for substrates, and similar Ki values for the inhibitor phosphonoacetaldehyde for both activities. The relative rates of the kinase activities for the bacterial and yeast enzymes are about 10(-4) and 4 x 10(-6) of their respective synthetase activities. These slow rates for the kinase reaction can be explained by the slow dissociation of ADP and formyl phosphate from the enzyme. This conclusion is supported by rapid-quench studies where a "burst" of ADP formation (6.4 s-1) was observed that is considerably faster than the steady-state rate (0.024 s-1). The demonstration of enzyme-bound products by a micropartition assay and the lack of a significant formate-stimulated exchange between ADP and ATP provide further evidence for the slow release of the products from the enzyme. The synthesis of N10-CHO-H4folate when H4folate was added to the E-formyl phosphate-ADP complex is also characterized by a "burst" of product formation. The rate of this burst phase at 5 degrees C occurs with a rate constant of 18 s-1 compared to 14 s-1 for the overall reaction at the same temperature. These results provide further evidence for formyl phosphate as an intermediate in the reaction and are consistent with the sequential mechanism of the normal catalytic pathway. Positional isotope exchange experiments using [beta,gamma-18O]ATP showed no evidence for exchange during turnover experiments in the presence of either H4folate or the competitive inhibitor pteroyltriglutamate. The absence of scrambling of the 18O label as observed by 31P NMR suggests that the central complex may impose restraints to limit free rotation of the P beta oxygens of the product ADP.     

ATP sulfurylase from the hyperthermophilic chemolithotroph Aquifex aeolicus

ATP sulfurylase from the hyperthermophilic chemolithotroph Aquifex aeolicus is a bacterial ortholog of the enzyme from filamentous fungi. (The subunit contains an adenosine 5'-phosphosulfate (APS) kinase-like, C-terminal domain.) The enzyme is highly heat stable with a half-life >1h at 90 degrees C. Steady-state kinetics are consistent with a random A-B, ordered P-Q mechanism where A=MgATP, B=SO4(2-), P=PP(i), and Q=APS. The kinetic constants suggest that the enzyme is optimized to act in the direction of ATP+sulfate formation. Chlorate is competitive with sulfate and with APS. In sulfur chemolithotrophs, ATP sulfurylase provides an efficient route for recycling PP(i) produced by biosynthetic reactions. However, the protein possesses low APS kinase activity. Consequently, it may also function to produce PAPS for sulfate ester formation or sulfate assimilation when hydrogen serves as the energy source and a reduced inorganic sulfur source is unavailable.     

The distribution of l-asparagine synthetase in the principal organs of several mammalian and avian species

1. Sulphate-dependent PP(i)-ATP exchange, catalysed by purified spinach leaf ATP sulphurylase, was correlated with the concentration of MgATP(2-) and MgP(2)O(7) (2-); ATP sulphurylase activity was not correlated with the concentration of free Mg(2+). 2. Sulphate-dependent PP(i)-ATP exchange was independent of PP(i) concentration, but dependent on the concentration of ATP and sulphate. The rate of sulphate-dependent PP(i)-ATP exchange was quantitatively defined by the rate equation applicable to the initial rate of a bireactant sequential mechanism under steady-state conditions. 3. Chlorate, nitrate and ADP inhibited the exchange reaction. The inhibition by chlorate and nitrate was uncompetitive with respect to ATP and competitive with respect to sulphate. The inhibition by ADP was competitive with respect to ATP and non-competitive with respect to sulphate. 4. ATP sulphurylase catalysed the synthesis of [(32)P]ATP from [(32)P]PP(i) and adenosine 5'-sulphatophosphate in the absence of sulphate; some properties of the reaction are described. Enzyme activity was dependent on the concentration of PP(i) and adenosine 5'-sulphatophosphate. 5. The synthesis of ATP from PP(i) and adenosine 5'-sulphatophosphate was inhibited by sulphate and ATP. The inhibition by sulphate was non-competitive with respect to PP(i) and adenosine 5'-sulphatophosphate; the inhibition by ATP was competitive with respect to adenosine 5'-sulphatophosphate and non-competitive with respect to PP(i). It was concluded that the reaction catalysed by spinach leaf ATP sulphurylase was ordered; expressing the order in the forward direction, MgATP(2-) was the first product to react with the enzyme and MgP(2)O(7) (2-) was the first product released. 6. The expected exchange reaction between sulphate and adenosine 5'-sulphatophosphate could not be demonstrated.