Deconstruction of the catalytic array within the amidotransferase subunit of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme consists of a large synthetase subunit, and a small amidotransferase subunit, which belongs to the Triad family of glutamine amidotransferases. Previous studies have established that the reaction mechanism of the small subunit proceeds through the formation of a gamma-glutamyl thioester with Cys-269. The roles in the hydrolysis of glutamine played by the conserved residues, Glu-355, Ser-47, Lys-202, and Gln-273, were determined by mutagenesis. In the X-ray crystal structure of the H353N mutant, Ser-47 and Gln-273 interact with the gamma-glutamyl thioester intermediate [Thoden, J. B., Miran, S. G., Phillips, J. C., Howard, A. J., Raushel, F. M., and Holden, H. M. (1998) Biochemistry 37, 8825-8831]. The mutants E355D and E355A have elevated values of K(m) for glutamine, but the overall carbamoyl phosphate synthesis reaction is unperturbed. E355Q does not significantly affect the bicarbonate-dependent ATPase or glutaminase partial reactions. However, this mutation almost completely uncouples the two partial reactions such that no carbamoyl phosphate is produced. The partial recovery of carbamoyl phosphate synthesis activity in the double mutant E355Q/K202M argues that the loss of activity in E355Q is at least partly due to additional interactions between Gln-355 and Lys-202 in E355Q. The mutants S47A and Q273A have elevated K(m) values for glutamine while the V(max) values are comparable to that of the wild-type enzyme. It is concluded that contrary to the original proposal for the catalytic triad, Glu-355 is not an essential residue for catalysis. The results are consistent with Ser-47 and Gln-273 playing significant roles in the binding of glutamine.     

15N isotope effects in glutamine hydrolysis catalyzed by carbamyl phosphate synthetase: evidence for a tetrahedral intermediate in the mechanism

15N isotope effects have been measured on the hydrolysis of glutamine catalyzed by carbamyl phosphate synthetase of Escherichia coli. The isotope effect in the amide nitrogen of glutamine is 1. 0217 at 37 degrees C with the wild-type enzyme in the presence of MgATP and HCO(3)(-) (overall reaction taking place). This V/K isotope effect indicates that breakdown of the tetrahedral intermediate formed with Cys 269 to release ammonia is the rate-limiting step in the hydrolysis. A full isotope effect of 1. 0215 is also seen in the partial reaction catalyzed by an E841K mutant enzyme, whose rate of glutamine hydrolysis is not affected by MgATP and HCO(3)(-). With wild-type enzyme in the absence of MgATP and HCO(3)(-), however, the (15)N isotope effect is reduced to 1. 0157. These isotope effects are interpreted in terms of partitioning of the tetrahedral intermediate whose rate of formation is dependent upon a conformation change which closes the active site after glutamine binding and prepares the enzyme for catalysis. An Ordered Uni Bi mechanism for glutamine hydrolysis that is consistent with the isotope effects and with the catalytic properties of the enzyme is proposed.     

Catalytic domains of carbamyl phosphate synthetase. Glutamine-hydrolyzing site of Escherichia coli carbamyl phosphate synthetase

We present evidence that cysteine 269 of the small subunit of Escherichia coli carbamyl phosphate synthetase is essential for the hydrolysis of glutamine. When cysteine 269 is replaced with glycine or with serine by site-directed mutagenesis of the carA gene, the resulting enzymes are unable to catalyze carbamyl phosphate synthesis with glutamine as nitrogen donor. Even though the glycine 269, and particularly the serine 269 enzyme bind significant amounts of glutamine, neither glycine 269 nor serine 269 can hydrolyze glutamine. The mutations at cysteine 269 do not affect carbamyl phosphate synthesis with NH3 as substrate. The NH3-dependent activity of the mutant enzymes was equal to that of wild-type. Measurements of Km indicate that the enzyme uses unionized NH3 rather than ammonium ion as substrate. The apparent Km for NH3 of the wild-type enzyme is calculated to be about 5 mM, independent of pH. The substitution of cysteine 269 with glycine or with serine results in a decrease of the apparent Km value for NH3 from 5 mM with the wild-type to 3.9 mM with the glycine, and 2.9 mM with the serine enzyme. Neither the glycine nor the serine mutation at position 269 affects the ability of the enzyme to catalyze ATP synthesis from ADP and carbamyl phosphate. Allosteric properties of the large subunit are also unaffected. However, substitution of cysteine 269 with glycine or with serine causes an 8- and 18-fold stimulation of HCO-3 -dependent ATPase activity, respectively. The increase in ATPase activity and the decrease in apparent Km for NH3 provide additional evidence for an interaction of the glutamine binding domain of the small subunit with one of the two known ATP sites of the large subunit.     

Reversible reaction of cyanate with a reactive sulfhydryl group at the glutamine binding site of carbamyl phosphate synthetase.

Carbamyl phosphate synthetase from Escherichia coli reacts stoichiometrically (one to one) with [14C]cyanate to give a 14C-labeled complex which can be isolated by gel filtration. The formation of the complex is prevented if L-glutamine is present or if the enzyme is first reacted with 2-amino-4-oxo-5-chloropentanoic acid, a chloro ketone analog of glutamine which has been shown to react with a specific SH group in the glutamine binding site. The rate of complex formation is increased by ADP and decreased by ATP and HCO3-. The isolated complex is inactive with respect to glutamine-dependent synthetase activity. However, the reaction of cyanate with the enzyme is reversible. The rate of dissociation of the isolated complex is not affected by pH (over the pH range 6-10), is greatly increased by ATP and HCO3-, and is decreased by ADP. The allosteric effectors ornithine and UMP have no effect on either the rate of formation or the rate of dissociation of the complex; however, the apparent affinity of the enzyme for ATP is decreased by UMP and increased by ornithine. The site of reaction of cyanate with carbamyl phosphate synthetase, which is composed of a light and a heavy subunit, is with an SH group in the light subunit to give an S-carbamylcysteine residue. The binding of L-[14C]glutamine to the enzyme and the inhibition of glutamine-dependent synthetase activity by the chloroketone analog are both prevented by the presence of cyanate. The reaction with cyanate is considered to be with the same essential SH group which is located in the glutamine binding site and is alkylated by 2-amino-4-oxo-5-chloropentanoic acid. The bicarbonate-dependent effects of ATP suggest that formation of the activated carbon dioxide intermediate is accompanied by changes in the heavy subunit which functionally alter the properties of the glutamine binding site on the light subunit. The allosteric effects of ornithine and UMP are probably not related to this intersubunit interaction.     

Carbamoyl-phosphate synthetase II of the mammalian CAD protein: kinetic mechanism and elucidation of reaction intermediates by positional isotope exchange

The kinetic mechanism of carbamoyl-phosphate synthetase II from Syrian hamster kidney cells has been determined at pH 7.2 and 37 degrees C. Initial velocity, product inhibition, and dead-end inhibition studies of both the biosynthetic and bicarbonate-dependent adenosinetriphosphatase (ATPase) reactions are consistent with a partially random sequential mechanism in which the ordered addition of MgATP, HCO3-, and glutamine is followed by the ordered release of glutamate and Pi. Subsequently, the binding of a second MgATP is followed by the release of MgADP, which precedes the random release of carbamoyl phosphate and a second MgADP. Carbamoyl-phosphate synthetase II catalyzes beta gamma-bridge:beta-nonbridge positional oxygen exchange of [gamma-18O]ATP in both the ATPase and biosynthetic reactions. Negligible exchange is observed in the strict absence of HCO3- (and glutamine or NH4+). The ratio of moles of MgATP exchanged to moles of MgATP hydrolyzed (nu ex/nu cat) is 0.62 for the ATPase reaction, and it is 0.39 and 0.16 for the biosynthetic reaction in the presence of high levels of glutamine and NH4+, respectively. The observed positional isotope exchange is suppressed but not eliminated at nearly saturating concentrations of either glutamine or NH4+, suggesting that this residual exchange results from either the facile reversal of an E-MgADP-carboxyphosphate-Gln(NH4+) complex or exchange within an E-MgADP-carbamoyl phosphate-MgADP complex, or both. In the 31P NMR spectra of the exchanged [gamma-18O]ATP, the distribution patterns of 16O in the gamma-phosphorus resonances in all samples reflect an exchange mechanism in which a rotationally unhindered molecule of [18O3, 16O]Pi does not readily participate. These results suggest that the formation of carbamate from MgATP, HCO3-, and glutamine proceeds via a stepwise, not concerted mechanism, involving at least one kinetically competent covalent intermediate, such as carboxyphosphate.     

Mechanistic investigations of Escherichia coli cytidine-5'-triphosphate synthetase. Detection of an intermediate by positional isotope exchange experiments

CTP synthetase from Escherichia coli catalyzes exchange of 18O from the beta gamma-bridge position of [gamma-18O4] ATP into the beta-nonbridge position. This positional isotope exchange occurs in the presence of UTP and MgCl2 but in the absence of NH3. The enzyme also has an ATPase activity in the presence of UTP that occurs under conditions that are identical to those used in the positional isotope exchange experiments. These data provide evidence for the stepwise nature of the reactions catalyzed by CTP synthetase with the initial step involving phosphorylation of UTP by ATP. The relative rate of the isotope exchange reaction is approximately 3 times faster than the ATPase reaction, but the isotope exchange rate is approximately 3% of the overall rate in the presence of NH3. These results are consistent with the ATPase reaction involving attack of water on the phosphorylated intermediate (4-phospho-UTP). The positional isotope exchange reaction is independent of the UTP concentration above saturating levels of UTP demonstrating that the order of addition of substrates is UTP followed by ATP and then NH3.     

Role of the four conserved histidine residues in the amidotransferase domain of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the formation of carbamoyl phosphate from ATP, bicarbonate, and glutamine. The amidotransferase activity of this enzyme is catalyzed by the smaller of the two subunits of the heterodimeric protein. The roles of four conserved histidine residues within this subunit were probed by site-directed mutagenesis to asparagine. The catalytic activities of the H272N and H341N mutants are not significantly different than that of the wild-type enzyme. The H353N mutant is unable to utilize glutamine as a nitrogen source in the synthetase reaction or the partial glutaminase reaction. However, binding to the glutamine active site is not impaired in the H353N enzyme since glutamine is found to activate the partial ATPase reaction by 40% with a Kd of 54 microM. The H312N mutant has a Michaelis constant for glutamine that is 2 orders of magnitude larger than the wild-type value, but the maximal rate of glutamine hydrolysis is unchanged. These results are consistent with His-353 functioning as a general acid/base catalyst for proton transfers while His-312 serves a critical role for the binding of glutamine to the active site.     

An engineered blockage within the ammonia tunnel of carbamoyl phosphate synthetase prevents the use of glutamine as a substrate but not ammonia

The heterodimeric carbamoyl phosphate synthetase (CPS) from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme catalyzes the hydrolysis of glutamine within the small amidotransferase subunit and then transfers ammonia to the two active sites within the large subunit. These three active sites are connected via an intermolecular tunnel, which has been located within the X-ray crystal structure of CPS from E. coli. It has been proposed that the ammonia intermediate diffuses through this molecular tunnel from the binding site for glutamine within the small subunit to the phosphorylation site for bicarbonate within the large subunit. To provide experimental support for the functional significance of this molecular tunnel, residues that define the interior walls of the "ammonia tunnel" within the small subunit were targeted for site-directed mutagenesis. These structural modifications were intended to either block or impede the passage of ammonia toward the large subunit. Two mutant proteins (G359Y and G359F) display kinetic properties consistent with a constriction or blockage of the ammonia tunnel. With both mutants, the glutaminase and bicarbonate-dependent ATPase reactions have become uncoupled from one another. However, these mutant enzymes are fully functional when external ammonia is utilized as the nitrogen source but are unable to use glutamine for the synthesis of carbamoyl-P. These results suggest the existence of an alternate route to the bicarbonate phosphorylation site when ammonia is provided as an external nitrogen source.     

Partial randomization of the four sequential amidation reactions catalyzed by cobyric acid synthetase with a single point mutation

Cobyric acid synthetase (CbiP) from Salmonella typhimurium catalyzes the glutamine and ATP-dependent amidation of carboxylates b, d, e, and g within adenosyl cobyrinic acid a,c-diamide. After each round of catalysis the partially amidated intermediates are released into solution and the four carboxylates are amidated in the sequential order of e, d, b, and g for the wild type enzyme. In the presence of [gamma-18O4]-ATP and adenosyl cobyrinic a,c-diamide the enzyme will catalyze the positional isotope exchange of the betagamma-bridge oxygen with the two beta-nonbridge oxygens. These results support the proposal that ATP is used to activate the carboxylate groups via the formation of a phosphorylated intermediate. CbiP catalyzes the hydrolysis of glutamine in the absence of ATP or adenosyl cobyrinic acid a,c-diamide, but the rate of glutamine hydrolysis is enhanced by a factor of 60 in the presence of these two substrates together. This result suggests that the formation of the phosphorylated intermediate is coupled to the activation of the site utilized for the hydrolysis of glutamine. However, the rate of glutamine hydrolysis is approximately 2.5 times the rate of ADP formation, indicating that the two active sites are partially uncoupled from one another and that some of the ammonia from glutamine hydrolysis leaks into the bulk solution. The mutation of D146 to either alanine or asparagine results in a protein that is able to catalyze the formation of cobyric acid. However, the strict amidation order observed with the wild type CbiP is partially randomized with carboxylate b being amidated last. With the D146N mutant, the predominant pathway occurs in the sequence d, e, g, and b. It is proposed that this residue enforces the amidation order in the wild type enzyme via charge-charge repulsion between the side chain carboxylate and the carboxylates of the substrate.     

On the intermediacy of carboxyphosphate in biotin-dependent carboxylations

In the ATP-dependent carboxylation of biotin that is catalyzed by most biotin-dependent carboxylases, a fundamental mechanistic question is whether the ATP activates bicarbonate (via the formation of carboxyphosphate as an intermediate) or whether the ATP activates biotin (via the formation of O-phosphobiotin). We have resorted to three mechanistic tests using the biotin carboxylase subunit of acetyl-CoA carboxylase from Escherichia coli: positional isotope exchange, intermediate trapping, and 18O tracer experiments on the ATPase activity. First, no catalysis of positional isotope exchange in adenosine 5'-[( alpha, beta-18O, beta, beta-18O2]triphosphate) was observed when either biotin or bicarbonate was absent, nor was any exchange seen in the presence of both N-1-methylbiotin and bicarbonate. Second, the putative carboxyphosphate intermediate could not be trapped as its trimethyl ester, under conditions of incubation and analysis where the authentic triester was shown to be adequately stable. In the third test, however, we showed that the ATPase activity of biotin carboxylase that is seen in the absence of biotin, an activity that is known to parallel the normal carboxylase reaction when biotin is present, occurs with the transfer of an 18O label directly from [18O]bicarbonate into the product Pi. This result suggests that the bicarbonate-dependent biotin-independent ATPase reaction catalyzed by biotin carboxylase goes via carboxyphosphate and that the carboxylation of biotin itself may proceed analogously.     

Inactivation of the amidotransferase activity of carbamoyl phosphate synthetase by the antibiotic acivicin.

Carbamoyl phosphate synthetase (CPS) from Escherichia coli catalyzes the formation of carbamoyl phosphate from 2 mol of ATP, bicarbonate, and glutamine. CPS was inactivated by the glutamine analog, acivicin. In the presence of ATP and bicarbonate the second-order rate constant for the inactivation of the glutamine-dependent activities was 4.0 x 10(4) m(-1) s(-1). In the absence of ATP and bicarbonate the second-order rate constant for inactivation of CPS was reduced by a factor of 200. The enzyme was protected against inactivation by the inclusion of glutamine in the reaction mixture. The ammonia-dependent activities were unaffected by the incubation of CPS with acivicin. These results are consistent with the covalent labeling of the glutamine-binding site located within the small amidotransferase subunit. The binding of ATP and bicarbonate to the large subunit of CPS must also induce a conformational change within the amidotransferase domain of the small subunit that enhances the nucleophilic character of the thiol group required for glutamine hydrolysis. The acivicin-inhibited enzyme was crystallized, and the three-dimensional structure was determined by x-ray diffraction techniques. The thiol group of Cys-269 was covalently attached to the dihydroisoxazole ring of acivicin with the displacement of a chloride ion.     

Dissection of the functional domains of Escherichia coli carbamoyl phosphate synthetase by site-directed mutagenesis

The catalytic functions of the amino-terminal and carboxyl-terminal halves of the large subunit of carbamoyl phosphate synthetase from Escherichia coli have been identified using site-directed mutagenesis. Glycine residues at positions 176, 180, and 722 within the putative mononucleotide-binding site were replaced with isoleucine residues. Each of these mutations resulted in at least a 1 order of magnitude reduction in the Vmax for carbamoyl phosphate synthesis. The mutations on the amino-terminal half, G176I and G180I, caused slight reduction in the rate of synthesis of ATP from ADP and carbamoyl phosphate (the partial ATP synthesis reaction) but the bicarbonate-dependent ATPase reaction velocity was reduced to less than 10% of the wild-type rate. The mutant G722I, which is on the carboxy-terminal half, caused the partial ATP synthesis reaction to be reduced by 1 order of magnitude but the bicarbonate-dependent ATPase reaction was reduced only slightly. All three mutations are within regions which show homology to the putative glycine-rich loops of many ATP-binding proteins. These results have been interpreted to suggest that the two homologous halves of the large subunit of carbamoyl phosphate synthetase each contain a binding site for ATP. The NH2-terminal domain contains the portion of the large subunit that is primarily involved with the phosphorylation of bicarbonate to carboxy phosphate while the COOH-terminal domain contains the region of the enzyme that catalyzes the phosphorylation of carbamate to carbamoyl phosphate.     

The gammaepsilon-c subunit interface in the ATP synthase of Escherichia coli. cross-linking of the epsilon subunit to the c subunit ring does not impair enzyme function, that of gamma to c subunits leads to uncoupling

Mutants with a cysteine residue in the gamma subunit at position 207 and the epsilon subunit at position 31 were expressed in combination with a c-dimer construct, which contains a single cysteine at position 42 of the second c subunit. These mutants are called gammaY207C/cc'Q42C and epsilonE31C/cc'Q42C, respectively. Cross-linking of epsilon to the c subunit ring was obtained almost to completion without significant effect on any enzyme function, i.e. ATP hydrolysis, ATP synthesis, and ATP hydrolysis-driven proton translocation were all close to that of wild type. The gamma subunit could also be linked to the c subunit ring in more than 90% yield, but this affected coupling. Thus, ATP hydrolysis was increased 2. 5-fold, ATP synthesis was dramatically decreased, and ATP hydrolysis-driven proton translocation was abolished, as measured by the 9-amino-6-chloro-2-methoxyacridinequenching method. These results for epsilonE31C/cc'Q42C indicate that the c subunit ring rotates with the central stalk element. That the gamma-epsilon cross-linked enzyme retains ATPase activity also argues for a gammaepsilon-c subunit rotor. However, the uncoupling induced by cross-linking of gamma to the c subunit ring points to important conformational changes taking place in the gammaepsilon-c subunit interface during this. Blocking these structural changes by cross-linking leads to a proton leak within the F(0).     

Analysis of ping-pong reaction mechanisms by positional isotope exchange. Application to galactose-1-phosphate uridyltransferase

A new positional isotope exchange method has been developed that can be used for the analysis of enzyme-catalyzed reactions which have ping-pong kinetic mechanisms. The technique can be used to measure the relative rates of ligand dissociation from enzyme-product complexes. Enzyme is incubated with the labeled substrate and an excess of the corresponding unlabeled product. The partitioning of the enzyme-product complex back toward free enzyme is determined from the rate of positional isotope exchange within the original labeled substrate. The partitioning of the enzyme-product complex forward toward free enzyme is determined from the rate of formation of totally unlabeled substrate. It has been shown that the ratio of the two rates provides a lower limit for the release of product from the enzyme-product complex. The technique has been applied to the reaction catalyzed by galactose-1-phosphate uridyltransferase. The lower limit for the release of glucose 1-phosphate from the uridyl-enzyme relative to the maximal velocity of the reverse reaction was determined to be 3.4 +/- 0.5.     

Cross-linking of the gamma subunit of the Escherichia coli ATPase (ECF1) via cysteines introduced by site-directed mutagenesis.

The gamma subunit of the Escherichia coli F1 ATPase (ECF1) has been altered by site-directed mutagenesis to create five different mutants, gamma-S8C, gamma-S81C, gamma-T106C, gamma-S179C, and gamma-V286C, respectively. ECF1 isolated from four of these mutants had ATPase activities similar to that of a wild-type isogenic strain used as a control, the exception was enzyme isolated from mutant gamma-S81C, which had an ATPase activity of around 70-80% of the wild type. ECF1 isolated from each of the various mutants was reacted with N-(4-(7-(diethylamino)-4-methylcoumarin-3-yl))maleimide (CM). The fluorescent reagent was incorporated into Cys residues placed at positions 8, 106, 179, and 286, but not at 81, indicating which of these Cys residues are on the surface of the gamma subunit in the enzyme complex. Modification of the Cys at position 106 with CM activated the enzyme, and modification of the Cys at position 8 inhibited ATPase activity a small amount; however, modification of Cys at 179 or 286 had no effect on enzyme activity. The four mutants with a reactive Cys were reacted with tetrafluorophenylazide maleimides (TFPAMs), novel photoactivatable cross-linkers. In the mutant gamma-S8C, cross-links were formed between the introduced Cys on the gamma subunit and sites on the beta subunit. This cross-linking between gamma and beta depended on nucleotide conditions under which the photolysis was carried out, with differently migrating cross-linked products being obtained in ATP + EDTA compared with ATP + Mg2+ or ATP + Mg2+ Pi. Cross-linking between beta and gamma inhibited ATPase activity in proportion to the yield of cross-linked product. In the mutant gamma-V286C, cross-links were formed between the introduced Cys on gamma and the alpha subunit which were the same in all nucleotide conditions and which led to inhibition of ATPase activity.     

A central swivel point in the RFC clamp loader controls PCNA opening and loading on DNA

Replication factor C (RFC) is a five-subunit complex that loads proliferating cell nuclear antigen (PCNA) clamps onto primer-template DNA (ptDNA) during replication. RFC subunits belong to the AAA(+) superfamily, and their ATPase activity drives interactions between the clamp loader, the clamp, and the ptDNA, leading to topologically linked PCNA·ptDNA. We report the kinetics of transient events in Saccharomyces cerevisiae RFC-catalyzed PCNA loading, including ATP-induced RFC activation, PCNA opening, ptDNA binding, ATP hydrolysis, PCNA closing, and PCNA·ptDNA release. This detailed perspective enables assessment of individual RFC-A, RFC-B, RFC-C, RFC-D, and RFC-E subunit functions in the reaction mechanism. Functions have been ascribed to RFC subunits previously based on a steady-state analysis of 'arginine-finger' ATPase mutants; however, pre-steady-state analysis provides a different view. The central subunit RFC-C serves as a critical swivel point in the clamp loader. ATP binding to this subunit initiates RFC activation, and the clamp loader adopts a spiral conformation that stabilizes PCNA in a corresponding open spiral. The importance of RFC subunit response to ATP binding decreases as RFC-C>RFC-D>RFC-B, with RFC-A being unnecessary. RFC-C-dependent activation of RFC also enables ptDNA binding, leading to the formation of the RFC·ATP·PCNA(open)·ptDNA complex. Subsequent ATP hydrolysis leads to complex dissociation, with RFC-D activity contributing the most to rapid ptDNA release. The pivotal role of the RFC-B/C/D subunit ATPase core in clamp loading is consistent with the similar central location of all three ATPase active subunits of the Escherichia coli clamp loader.     

The role of the epsilon subunit in the Escherichia coli ATP synthase. The C-terminal domain is required for efficient energy coupling

The role of the C-domain of the epsilon subunit of ATP synthase was investigated by fusing either the 20-kDa flavodoxin (Fd) or the 5-kDa chitin binding domain (CBD) to the N termini of both full-length epsilon and a truncation mutant epsilon(88-stop). All mutant epsilon proteins were stable in cells and supported F1F0 assembly. Cells expressing the Fd-epsilon or Fd-epsilon(88-stop) mutants were unable to grow on acetate minimal medium, indicating their inability to carry out oxidative phosphorylation because of steric blockage of rotation. The other forms of epsilon supported growth on acetate. Membrane vesicles containing Fd-epsilon showed 23% of the wild type ATPase activity but no proton pumping, suggesting that the ATP synthase is intrinsically partially uncoupled. Vesicles containing CBD-epsilon were indistinguishable from the wild type in ATPase activity and proton pumping, indicating that the N-terminal fusions alone do not promote uncoupling. Fd-epsilon(88-stop) caused higher rates of uncoupled ATP hydrolysis than Fd-epsilon, and epsilon(88-stop) showed an increased rate of membrane-bound ATP hydrolysis but decreased proton pumping relative to the wild type. Both results demonstrate the role of the C-domain in coupling. Analysis of the wild type and epsilon(88-stop) mutant membrane ATPase activities at concentrations of ATP from 50 mum to 8 mm showed no significant dependence of the ratio of bound/released ATPase activity on ATP concentration. These results support the hypothesis that the main function of the C-domain in the Escherichia coli epsilon subunit is to reduce uncoupled ATPase activity, rather than to regulate coupled activity.     

Isoleucine 10 is essential for DNA gyrase B function in Escherichia coli

DNA gyrase is an essential enzyme that regulates the DNA topology in bacteria. It belongs to the type II DNA topoisomerase family and is responsible for the introduction of negative supercoils into DNA at the expense of hydrolysis of ATP molecules. The aim of the present work was to study the contribution of I10, one of the most important residues responsible for the stabilization of GyrB dimer and involved in the ATP-binding step, in the ATP-hydrolysis reaction and in the DNA supercoiling mechanism. We constructed MBP-tagged GyrB mutants I10G and Delta4-14. Our results demonstrate that both mutations severely affect the DNA-dependent ATPase activity and DNA supercoiling. Mutation of Y5 residue involved in the formation of ATPase catalytic site (Y5G mutant) had only little effect on the DNA-dependent ATPase activity and DNA supercoiling. Interestingly, the DNA-relaxation activity of MBP-GyrB mutants and wild type was completely inhibited by ATP. Binding of ADPNP to MBP-tagged mutants was significantly decreased. ADPNP had no effect on DNA-relaxation activity of MBP-tagged mutants but was able to inhibit MBP-tagged wild type enzyme. Our results demonstrate that GyrB N-terminal arm, and specially I10 residue is essential for ATP binding/hydrolysis efficiency and DNA transfer through DNA gyrase.     

Monitoring the timing of ATP hydrolysis with activation of peptide cleavage in Escherichia coli Lon by transient kinetics

Escherichia coli Lon, also known as protease La, is an oligomeric ATP-dependent protease, which functions to degrade damaged and certain short-lived regulatory proteins in the cell. To investigate the kinetic mechanism of E. coli Lon protease, we performed the first pre-steady-state kinetic characterization of the ATPase and peptidase activities of this enzyme. Using rapid quench-flow and fluorescence stopped-flow spectroscopy techniques, we demonstrated that ATP hydrolysis occurs before peptide cleavage, with the former reaction displaying a burst and the latter displaying a lag in product production. The detection of burst kinetics in ATP hydrolysis is indicative of a step after nucleotide hydrolysis being rate-limiting in ATPase turnover. At saturating substrate concentrations, the lag rate constant for peptide cleavage is comparable to the kcat of ATPase, indicating that two hydrolytic processes are coordinated during the first enzyme turnover. The involvement of subunit interaction during enzyme catalysis was detected as positive cooperativity in the binding and hydrolysis of substrates, as well as apparent asymmetry in the ATPase activity in Lon. When our data are taken together, they are consistent with a reaction model in which ATP hydrolysis is used to generate an active enzyme form that hydrolyzes peptide.     

Kinetic evidence for the formation of D-alanyl phosphate in the mechanism of D-alanyl-D-alanine ligase

The steady state kinetic mechanism, molecular isotope exchange and the positional isotope exchange (PIX) reactions of D-alanyl-D-alanine ligase from Salmonella typhimurium have been studied. The kinetic mechanism has been determined to be ordered Ter-Ter from initial velocity and product inhibition experiments. The first substrate to bind is ATP followed by the addition of 2 mol of D-alanine. Pi is released, and then D-alanyl-D-alanine and ADP dissociate from the enzyme surface. In the reverse direction D-alanyl-D-alanine exhibits complete substrate inhibition (Ki = 1.15 +/- 0.05 mM) by binding to the enzyme-ATP complex. In the presence of D-alanine, D-alanyl-D-alanine ligase catalyzed the positional exchange of the beta,gamma-bridge oxygen in [gamma-18O4]ATP to a beta-nonbridge position. Two possible alternate dead-end substrate analogs, D-2-chloropropionic acid and isobutyric acid, did not induce a positional isotope exchange in [gamma-18O4]ATP. The positional isotope exchange rate is diminished relative to the net substrate turnover as the concentration of D-alanine is increased. This is consistent with the ordered Ter-Ter mechanism as determined by the steady state kinetic experiments. The ratio of the positional isotope exchange rate relative to the net chemical turnover of substrate (Vex/Vchem) approaches a value of 1.4 as the concentration of D-alanine becomes very small. This ratio is 100 times larger than the ratio of the maximal reverse and forward chemical reaction velocities (V2/V1). This situation is only possible when the reaction mechanism proceeds in two distinct steps and the first step is much faster than the second step. The enzyme was also found to catalyze the molecular isotope exchange of radiolabeled D-alanine with D-alanyl-D-alanine in the presence of phosphate. These results are consistent with the formation of D-alanyl phosphate as a kinetically competent intermediate.