Further assessment of the construct validity of four measures of narcissism: replication and extension.

CT. The authors build on earlier research by L. S. Mullins and R. E. Kopelman (1988) and R. E. Kopelman and L. S. Mullins (1992) to reexamine the construct validity of four narcissism scales: the Margolis-Thomas Measure of Narcissism (MT; H. D. Margolis & V. A. Thomas, 1980), the Narcissistic Personality Disorder Scale (NPDS; H. U. Ashby, R. R. Lee, & E. H. Duke, 1979), the Narcissism-Hypersensitivity subscale of the MMPI, Scale 5, Masculinity-Femininity (NHMF; K. Serkownek, 1975), and the Narcissistic Personality Inventory (NPI; R. Raskin & C. S. Hall, 1979). The present analysis included the revised NPI and its factors along with four measures of satisfaction and a number of other previously assessed variables. The MT exhibited the strongest validity, correlating positively with conceptually related constructs such as Machiavellianism, nonsignificantly with unrelated measures like the need to achieve, and inversely with all four satisfaction scales. Contrasts between the NPI and NPDS and NHMF seemed to parallel recent differentiations between overt and covert narcissism, but data for the NPI factors suggested instead that the four narcissism scales helped describe a complex psychological continuum related to adjustment.

D-Ala-D-X ligases: evaluation of D-alanyl phosphate intermediate by MIX, PIX and rapid quench studies.

BACKGROUND: The D-alanyl-D-lactate (D-Ala-D-Lac) ligase is required for synthesis of altered peptidoglycan (PG) termini in the VanA phenotype of vancomycin-resistant enterococci (VRE), and the D-alanyl-D-serine (D-Ala-D-Ser) ligase is required for the VanC phenotype of VRE. Here we have compared these with the Escherichia coli D-Ala-D-Ala ligase DdlB for formation of the enzyme-bound D-alanyl phosphate, D-Ala(1)-PO(3)(2-) (D-Ala(1)-P), intermediate. RESULTS: The VanC2 ligase catalyzes a molecular isotope exchange (MIX) partial reaction, incorporating radioactivity from (14)C-D-Ser into D-Ala-(14)C-D-Ser at a rate of 0.7 min(-1), which approaches kinetic competence for the reversible D-Ala(1)-P formation from the back direction. A positional isotope exchange (PIX) study with the VanC2 and VanA ligases displayed a D-Ala(1)-dependent bridge to nonbridge exchange of the oxygen-18 label of [gamma-(18)O(4)]-ATP at rates of up to 0.6 min(-1); this exchange was completely suppressed by the addition of the second substrate D-Ser or D-Lac, respectively, as the D-Ala(1)-P intermediate was swept in the forward direction. As a third criterion for formation of bound D-Ala(1)-P, we conducted rapid quench studies to detect bursts of ADP formation in the first turnover of DdlB and VanA. With E. coli DdlB, there was a burst amplitude of ADP corresponding to 26-30% of the DdlB active sites, followed by the expected steady-state rate of 620-650 min(-1). For D-Ala-D-Lac and D-Ala-D-Ala synthesis by VanA, we measured a burst of 25-30% or 51% of active enzyme, respectively. CONCLUSIONS: These three approaches support the rapid (more than 1000 min(-1)), reversible formation of the enzyme intermediate D-Ala(1)-P by members of the D-Ala-D-X (where X is Ala, Ser or Lac) ligase superfamily.

The differentially conserved residues of carbamoyl-phosphate synthetase.

Carbamoyl-phosphate synthetase (CPS) from Escherichia coli is a heterodimeric protein. The larger of the two subunits (M(r) approximately 118,000) contains a pair of homologous domains of approximately 400 residues each that are approximately 40% identical in amino acid sequence. The carboxy phosphate (residues 1-400) and carbamoyl phosphate domains (residues 553-933) also contain approximately 79 differentially conserved residues. These are residues that are conserved throughout the bacterial evolution of CPS in one of these homologous domains but not the other. The role of these differentially conserved residues in the structural and catalytic properties of CPS was addressed by swapping segments of these residues from one domain to the other. Nine of these chimeric mutant enzymes were constructed, expressed, purified, and characterized. A majority of the mutants were unable to synthesize any carbamoyl phosphate and the rest were severely crippled. True tandem repeat chimeric proteins were constructed by the complete substitution of one homologous domain sequence for the other. Neither of the two possible chimeric proteins was structurally stable. These results have been interpreted to demonstrate that the two homologous domains in the large subunit of CPS are functionally and structurally nonequivalent. This nonequivalence is a direct result of the specific functions each of these domains must perform during the overall synthesis of carbamoyl phosphate in the wild type enzyme and the specific structural alterations imposed by the differentially conserved residues.

Allosteric dominance in carbamoyl phosphate synthetase.

A linked-function analysis of the allosteric responsiveness of carbamoyl phosphate synthetase (CPS) from E. coli was performed by following the ATP synthesis reaction at low carbamoyl phosphate concentration. All three allosteric ligands, ornithine, UMP, and IMP, act by modifying the affinity of CPS for the substrate MgADP. Individually ornithine strongly promotes, and UMP strongly antagonizes, the binding of MgADP. IMP causes only a slight inhibition at 25 degreesC. When both ornithine and UMP were varied, models which presume a mutually exclusive binding relationship between these ligands do not fit the data as well as does one which allows both ligands (and substrate) to bind simultaneously. The same result was obtained with ornithine and IMP. By contrast, the actions of UMP and IMP together must be explained with a competitive model, consistent with previous reports that UMP and IMP bind to the same site. When ornithine is bound to the enzyme, its activation dominates the effects when either UMP or IMP is also bound. The relationship of this observation to the structure of CPS is discussed.

A stringent test for the nucleotide switch mechanism of carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase (CPS) catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of MgATP. The X-ray crystal structure of the enzyme has revealed that the two nucleotide binding sites are separated by approximately 35 A. Isotopic oxygen exchange of 18O and 16O between solvent water and [13C]bicarbonate was measured using 13C NMR spectroscopy during substrate turnover in the presence and absence of glutamine as a nitrogen source. In the absence of added glutamine, CPS catalyzed the exchange of one oxygen atom from bicarbonate with solvent water during every turnover of the bicarbonate-dependent ATPase reaction. In the presence of added glutamine, there was no exchange of solvent water with bicarbonate during the enzymatic synthesis of carbamoyl phosphate, indicating that any carbon-containing intermediate in the reaction mechanism is committed to the formation of carbamoyl phosphate and is not subject to hydrolysis. These results are fully consistent with a chemical mechanism that requires the physical migration of the carbamate intermediate from the site of its formation within one of the nucleotide binding domains to the other nucleotide binding domain for subsequent phosphorylation by the second MgATP. These results are not compatible with a nucleotide switch mechanism. The nucleotide switch mechanism includes the synthesis of carbamoyl phosphate entirely within a single nucleotide binding domain and concurrent conformational changes driven by the bicarbonate-dependent hydrolysis of MgATP at the second nucleotide binding domain.

Conformational stability of ribonuclease T1 determined by hydrogen-deuterium exchange.

The hydrogen-deuterium exchange kinetics of 37 backbone amide residues in RNase T1 have been monitored at 25, 40, 45, and 50 degrees C at pD 5.6 and at 40 and 45 degrees C at pD 6.6. The hydrogen exchange rate constants of the hydrogen-bonded residues varied over eight orders of magnitude at 25 degrees C with 13 residues showing exchange rates consistent with exchange occurring as a result of global unfolding. These residues are located in strands 2-4 of the central beta-pleated sheet. The residues located in the alpha-helix and the remaining strands of the beta-sheet exhibited exchange behaviors consistent with exchange occurring due to local structural fluctuations. For several residues at 25 degrees C, the global free energy change calculated from the hydrogen exchange data was over 2 kcal/mol greater than the free energy of unfolding determined from urea denaturation experiments. The number of residues showing this unexpected behavior was found to increase with temperature. This apparent inconsistency can be explained quantitatively if the cis-trans isomerization of the two cis prolines, Pro-39 and Pro-55, is taken into account. The cis-trans isomerization equilibrium calculated from kinetic data indicates the free energy of the unfolded state will be 2.6 kcal/mol higher at 25 degrees C when the two prolines are cis rather than trans (Mayr LM, Odefey CO, Schutkowski M, Schmid FX. 1996. Kinetic analysis of the unfolding and refolding of ribonuclease T1 by a stopped-flow double-mixing technique. Biochemistry 35: 5550-5561). The hydrogen exchange results are consistent with the most slowly exchanging hydrogens exchanging from a globally higher free energy unfolded state in which Pro-55 and Pro-39 are still predominantly in the cis conformation. When the conformational stabilities determined by hydrogen exchange are corrected for the proline isomerization equilibrium, the results are in excellent agreement with those from an analysis of urea denaturation curves.

Mechanism-based inhibitors for the inactivation of the bacterial phosphotriesterase.

1-Bromovinyl (I), Z-2-bromovinyl (II), 1,2-dibromoethyl (III), and a series of 4-(halomethyl)-2-nitrophenyl (IVa-c) diethyl phosphate esters were examined as substrates and mechanism-based inhibitors for the bacterial phosphotriesterase. All of these compounds were found to act as substrates for the enzyme. Inhibitor I rapidly inactivated the enzyme within 1 min, giving a partition ratio of 230. The newly formed covalent adduct with inhibitor I was susceptible to hydrolysis at elevated values of pH and dissociation by NH2OH. Azide was not able to protect the enzyme from inactivation with inhibitor I, implying that the reactive species was not released into solution prior to the inactivation event. The reactive species was proposed to be either an acyl bromide or a ketene intermediate formed by the enzymatic hydrolysis of inhibitor I. Compounds II and III were shown to be relatively poor substrates of phosphotriesterase and they did not induce any significant inactivation of the enzyme. The inhibitor, 4-(bromomethyl)-2-nitrophenyl diethyl phosphate (IVa), was found to irreversibly inactivate the enzyme with a KI = 7.9 mM and kinact = 1. 2 min-1 at pH 9.0. There was no effect on the rate of inactivation upon the addition of the exogenous nucleophiles, azide, and NH2OH. The species responsible for the covalent modification of the enzyme by IVa was most likely a quinone methide formed by the elimination of bromide from the phenolic intermediate. NMR experiments demonstrated that the quinone methide did not accumulate in solution. The chloro (IVb) and fluoro (IVc) analogues did not inactivate the enzyme. These results suggest that the elimination of the halide ion from the phenolic intermediate largely determines the partition ratio for inactivation.

Role of conserved residues within the carboxy phosphate domain of carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase (CPS) catalyzes the formation of carbamoyl phosphate from glutamine, bicarbonate, and 2 mol of MgATP. The heterodimeric protein is composed of a small amidotransferase subunit and a larger synthetase subunit. The synthetase subunit contains a large tandem repeat for each of the nucleotides used in the overall synthesis of carbamoyl phosphate. A working model for the three-dimensional fold of the carboxy phosphate domain of CPS was constructed on the basis of amino acid sequence alignments and the X-ray crystal structure coordinates for biotin carboxylase and D-alanine:D-alanine ligase. This model was used to select ten residues within the carboxy phosphate domain of CPS for modification and subsequent characterization of the kinetic constants for the mutant proteins. Residues R82, R129, R169, D207, E215, N283, and Q285 were changed to alanine residues; residues E299 and R303 to glutamine; and residue N301 to aspartate. No significant changes in the catalytic constants were observed upon mutation of either R82 or D207, and thus these residues appear to be nonessential for binding and/or catalytic activity. The Michaelis constant for ATP was most affected by modification of residues R129, R169, Q285, and N301. The binding of bicarbonate was most affected by the mutagenesis of residues E215, E299, N301, and R303. The mutation of residues E215, N283, E299, N301, and R303 resulted in proteins which were unable to synthesize carbamoyl phosphate at a significant rate. All of the mutations, with the exception of the N301D mutant, primarily affected the enzyme by altering the step for the phosphorylation of bicarbonate. However, mutation of N301 to aspartic acid also disrupted the catalytic step involved in the phosphorylation of carbamate. These results are consistent with a role for the N-terminal half of the synthetase subunit of CPS that is primarily directed at the initial phosphorylation of bicarbonate by the first ATP utilized in the overall synthesis of carbamoyl phosphate. The active site structure appears to be very similar to the ones previously determined for D-alanine:D-alanine ligase and biotin carboxylase.

Comparison of the functional differences for the homologous residues within the carboxy phosphate and carbamate domains of carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase (CPS) from Escherichia coli catalyzes the formation of carbamoyl phosphate from two molecules of MgATP, bicarbonate, and glutamine. It has been previously shown that the amino- and carboxy-terminal halves of the large subunit of this protein are homologous. A working model for the active site structure of the carboxy-terminal domain of the large subunit of CPS was constructed based upon amino acid sequence alignments and the previously determined three-dimensional structures of two mechanistically related proteins, biotin carboxylase and D-alanine:D-alanine ligase. The model was tested by mutation of ten amino acid residues predicted to be important for binding and/or catalysis. The mutated residues were as follows: R571, R675, R715, D753, E761, N827, Q829, E841, N843, and R845. The mutant proteins were expressed, purified to homogeneity and the catalytic properties determined for a variety of assay formats. The mutants E761A, E841Q, N843D, and R845Q were diminished in their ability to synthesize carbamoyl phosphate. The R715A, Q829A, and R675A mutants displayed elevated Michaelis constants for MgADP in the partial back reaction. The mutants E761A, N827A, E841Q, N843D, and R845Q showed significant increases in the Michaelis constants for either bicarbonate or carbamoyl phosphate. No significant alterations were noted upon mutation of either R571 or D753 to an alanine residue and thus these amino acids do not appear essential for structure or catalytic activity. These results have been utilized to further support the proposal that the C-terminal half of the large subunit of CPS is primarily responsible for the phosphorylation of the carbamate intermediate during the final formation of carbamoyl phosphate. The measured effects on the catalyic activities displayed by these mutations were found to be comparable to the previously determined effects after mutation of the homologous residues located on the N-terminal half of CPS and also for those residues mutated within D-alanine:D-alanine ligase [Shi, Y., & Walsh, C.T. (1995) Biochemistry 34, 2768-2776].

Allosteric effects of carbamoyl phosphate synthetase from Escherichia coli are entropy-driven.

When catalyzing the formation of MgATP and carbamate from MgADP and carbamoyl phosphate, Escherichia coli carbamoyl phosphate synthetase (CPS) binds MgADP with a large negative change in heat capacity. The magnitude of this heat capacity change is not appreciably altered by the presence of a saturating concentration of either the allosteric activator ornithine or the inhibitor UMP despite the substantial and opposing effects these ligands have on the binding affinity for MgADP. By contrast, no detectable change in heat capacity is associated with the thermodynamic coupling between MgADP and either ornithine or UMP. The sign of the apparently constant enthalpic and entropic contributions to the coupling free energy for each of these ligands is opposite that of the coupling free energy, indicating that the observed allosteric phenomenology is in net opposed by the enthalpy of the interaction and instead arises from a change in entropy of the system. IMP produces only a very small allosteric effect as indicated by a near-zero value for the MgADP-IMP coupling free energy. However, the enthalpic and entropic contributions are individually larger in absolute value for the IMP coupling than for those pertaining to the other allosteric ligands, and entropy dominates the coupling free energy above 36 degrees C, causing IMP to become an activator at high temperature. In addition, the sign of the coupling enthalpy and entropy for IMP has the same sign as the coupling enthalpy and entropy produced by ornithine, suggesting that IMP and ornithine may similarly influence the enzyme at a molecular level despite binding to different allosteric sites on the enzyme. The data are consistent with a model in which the actions of the allosteric ligands arise primarily from changes in the conformational degeneracy introduced by each ligand. With this model, one can also rationalize the failure of these allosteric ligands to substantially influence kcat.

Are turns required for the folding of ribonuclease T1?

Ribonuclease T1 (RNase T1) is a small, globular protein of 104 amino acids for which extensive thermodynamic and structural information is known. To assess the specific influence of variations in amino acid sequence on the mechanism for protein folding, circularly permuted variants of RNase T1 were constructed and characterized in terms of catalytic activity and thermodynamic stability. The disulfide bond connecting Cys-2 and Cys-10 was removed by mutation of these residues to alanine (C2, 10A) to avoid potential steric problems imposed by the circular permutations. The original amino-terminus and carboxyl-terminus of the mutant (C2, 10A) were subsequently joined with a tripeptide linker to accommodate a reverse turn and new termini were introduced throughout the primary sequence in regions of solvent-exposed loops at Ser-35 (cp35S1), Asp-49 (cp49D1), Gly-70 (cp70G1), and Ser-96 (cp96S1). These circularly permuted RNase T1 mutants retained 35-100% of the original catalytic activity for the hydrolysis of guanylyl(3'-->5')cytidine, suggesting that the overall tertiary fold of these mutants is very similar to that of wild-type protein. Chemical denaturation curves indicated thermodynamic stabilities at pH 5.0 of 5.7, 2.9, 2.6, and 4.6 kcal/mol for cp35S1, cp49D1, cp70G1, and cp96S1, respectively, compared to a value of 10.1 kcal/mol for wild-type RNase T1 and 6.4 kcal/mol for (C2, 10A) T1. A fifth set of circularly permuted variants was attempted with new termini positioned in a tight beta-turn between Glu-82 and Gln-85. New termini were inserted at Asn-83 (cp83N1), Asn-84 (cp84N1), and Gln-85 (cp85Q1). No detectable amount of protein was ever produced for any of the mutations in this region, suggesting that this turn may be critical for the proper folding and/or thermodynamic stability of RNase T1.

Positional isotope exchange as probe of enzyme action.

The positional isotope exchange technique has been found to be quite useful for the identification of reaction intermediates in enzyme-catalyzed reactions. For reactions where intermediates are not expected the method can be used with great utility for the quantitative determination of the partitioning of enzyme-product complexes. However, it must be remembered that it has been explicitly assumed that the functional group undergoing positional exchange is free to rotate. This assumption is not always valid since examples have been discovered where the functional group rotation is indeed hindered. For instance, in the reaction catalyzed by argininosuccinate synthetase a PIX reaction was not observed on incubation of ATP and citrulline even though a citrulline-adenylate complex has been identified from rapid quench experiments.

Structural characterization of the divalent cation sites of bacterial phosphotriesterase by 113Cd NMR spectroscopy.

The phosphotriesterase from Pseudomonas diminuta catalyzes the hydrolysis of organophosphate esters. The isolated native protein contains zinc, and removal of this metal abolishes the enzymatic activity. Reconstitution of the apoenzyme requires 2 mol of cadmium per mol of protein for full catalytic activity. The kcat and Km values for the hydrolysis of paraoxon for the cadmium-substituted enzyme are 4300 s-1 and 390 microM, respectively. These values compare favorably with the kinetic constants observed for the zinc-substituted enzyme (2300 s-1 and 78 microM). A hybrid enzyme containing one zinc and one cadmium ion is catalytically active, and the kinetic constants are nearly identical to the values obtained with the all-zinc-containing enzyme. The NMR spectrum of protein reconstituted with two 113Cd2+ ions per enzyme molecule exhibits cadmium resonances at 212 and 116 ppm downfield from Cd(ClO4)2. The two metal ions are, therefore, in significantly different chemical environments. These two binding sites have been designated the M alpha and M beta sites for the low- and high-field signals, respectively. Protein substituted with a single cadmium ion also shows two cadmium resonances, and thus one site is not completely filled prior to the binding of metal to the other site. The Cd/Zn hybrid protein shows a single cadmium resonance at 115 ppm, and thus the cadmium is occupying the M beta site while zinc is occupying the M alpha site. The positions of the observed chemical shifts for the two cadmium signals indicate that the ligands to both metals are composed of a mixture of oxygen and nitrogen atoms.(ABSTRACT TRUNCATED AT 250 WORDS)

Investigation of ribonuclease T1 folding intermediates by hydrogen-deuterium amide exchange-two-dimensional NMR spectroscopy.

The rate of hydrogen bond formation at individual amino acid residues in ribonuclease T1 (RNase T1) has been investigated by the hydrogen-deuterium exchange-2D NMR (HDEx-2D NMR) technique (Udgaonkar & Baldwin, 1988; Rder et al., 1988) to gain insight into the mechanism and pathways of protein folding. The HDEx-2D NMR technique combines rapid mixing and 2D NMR methods to follow the protection of backbone amide deuterons from exchange with solvent protons as a function of folding time. The technique depends on the difference in the exchange rates of hydrogen-bonded and non-hydrogen-bonded amide residues so that as the protein folds, the amide residues involved in hydrogen bonding are protected from exchange with solvent to give structural information about early folding events. The observed time course for deuterium protection was followed for 24 backbone amide residues that form stable hydrogen bonds in RNase T1. The time courses are biphasic with 60-80% of the protein molecules showing rapid hydrogen bond formation (12-119 s-1) in the alpha-helix and the beta-sheet. The remaining 20-40% of the molecules are protected in a slow phase with a rate constant that has a lower limit of 0.01 s-1. If the rate constants in this first phase are arbitrarily subdivided into two classes, fast (> or = 25 s-1) and intermediate (< 25 s-1), then the amide residues that are found in the hydrophobic core are in the fast class while those located on the periphery of the three-dimensional structure are in the intermediate class.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the zinc binding site of bacterial phosphotriesterase.

The bacterial phosphotriesterase has been found to require a divalent cation for enzymatic activity. This enzyme catalyzes the detoxification of organophosphorus insecticides and nerve agents. In an Escherichia coli expression system significantly higher concentrations of active enzyme could be produced when 1.0 mM concentrations of Mn2+, Co2+, Ni2+, and Cd2+ were included in the growth medium. The isolated enzymes contained up to 2 equivalents of these metal ions as determined by atomic absorption spectroscopy. The catalytic activity of the various metal enzyme derivatives was lost upon incubation with EDTA, 1,10-phenanthroline, and 8-hydroxyquinoline-5-sulfonic acid. Protection against inactivation by metal chelation was afforded by the binding of competitive inhibitors, suggesting that at least one metal is at or near the active site. Apoenzyme was prepared by incubation of the phosphotriesterase with beta-mercaptoethanol and EDTA for 2 days. Full recovery of enzymatic activity could be obtained by incubation of the apoenzyme with 2 equivalents of Zn2+, Co2+, Ni2+, Cd2+, or Mn2+. The 113Cd NMR spectrum of enzyme containing 2 equivalents of 113Cd2+ showed two resonances at 120 and 215 ppm downfield from Cd(ClO4)2. The NMR data are consistent with nitrogen (histidine) and oxygen ligands to the metal centers.

Stopped-flow kinetic analysis of the bacterial luciferase reaction.

The kinetics of the reaction catalyzed by bacterial luciferase have been measured by stopped-flow spectrophotometry at pH 7 and 25 degrees C. Luciferase catalyzes the formation of visible light, FMN, and a carboxylic acid from FMNH2, O2, and the corresponding aldehyde. The time courses for the formation and decay of the various intermediates have been followed by monitoring the absorbance changes at 380 and 445 nm along with the emission of visible light using n-decanal as the alkyl aldehyde. The synthesis of the 4a-hydroperoxyflavin intermediate (FMNOOH) was monitored at 380 nm after various concentrations of luciferase, O2, and FMNH2 were mixed. The second-order rate constant for the formation of FMNOOH from the luciferase-FMNH2 complex was found to be 2.4 x 10(6) M-1 s-1. In the absence of n-decanal, this complex decays to FMN and H2O2 with a rate constant of 0.10 s-1. The enzyme-FMNH2 complex was found to isomerize prior to reaction with oxygen. The production of visible light reaches a maximum intensity within 1 s and then decays exponentially over the next 10 s. The formation of FMN from the intermediate pseudobase (FMNOH) was monitored at 445 nm. This step of the reaction mechanism was inhibited by high levels of n-decanal which indicated that a dead-end luciferase-FMNOH-decanal could form. The time courses for these optical changes have been incorporated into a comprehensive kinetic model. Estimates for 15 individual rate constants have been obtained for this model by numeric simulations of the various time courses.

Quantifying the allosteric properties of Escherichia coli carbamyl phosphate synthetase: determination of thermodynamic linked-function parameters in an ordered kinetic mechanism.

The effects of the allosteric ligands UMP, IMP, and ornithine on the partial reactions catalyzed by Escherichia coli carbamyl phosphate synthetase have been examined. Both of these reactions, a HCO3(-)-dependent ATP synthesis reaction and a carbamyl phosphate-dependent ATP synthesis reaction, follow bimolecular ordered sequential kinetic mechanisms. In the ATPase reaction, MgATP binds before HCO3- as established previously for the overall reaction catalyzed by carbamyl phosphate synthetase [Raushel, F. M., Anderson, P. M., & Villafranca, J. J. (1978) Biochemistry 17, 5587-5591]. The initial velocity kinetics for the ATP synthesis reaction indicate that MgADP binds before carbamyl phosphate in an equilibrium ordered mechanism except in the presence of ornithine. Determination of true thermodynamic linked-function parameters describing the impact of allosteric ligands on the binding interactions of the first substrate to bind in an ordered mechanism requires experiments to be performed in which both substrates are varied even if only one is apparently affected by the allosteric ligands. In so doing, we have found that IMP has little effect on the overall reaction of either of these two partial reactions. UMP and ornithine, which have a pronounced effect on the apparent Km for MgATP in the overall reaction, both substantially change the thermodynamic dissociation constant for MgADP from the binary E-MgADP complex, Kia, in the ATP synthesis reaction, with UMP increasing Kia 15-fold and ornithine decreasing Kia by 18-fold. By contrast, only UMP substantially affects the Kia for MgATP in the ATPase reaction, increasing it by 5-fold.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in the energetics of the carbamoyl phosphate synthetase reaction by site-directed modification of the essential sulfhydryl group.

The change in reaction energetics of the bicarbonate-dependent ATPase reaction of Escherichia coli carbamoyl phosphate synthetase has been investigated for two site-directed mutations of the essential cysteine in the small subunit. Cysteine 269 has been proposed to facilitate the hydrolysis of glutamine by the formation of a glutamyl-thioester intermediate. The two mutant enzymes, C269S and C269G, along with the isolated large subunit, exhibit a 2-2.6-fold increase in the bicarbonate-dependent ATPase reaction relative to that observed for the wild type enzyme. In the presence of glutamine the overall enhancement is 3.7 and 9.0 for the C269G and C269S mutant enzymes, respectively. Carboxyphosphate is an intermediate in the bicarbonate-dependent ATPase reaction. The cause of the rate enhancements was investigated by measuring the positional isotope exchange rate in [gamma-18O4] ATP relative to the net rate of ATP hydrolysis. This ratio (Vex/Vchem) is a measure of the partitioning of the enzyme-carboxyphosphate-ADP complex. The partitioning ratio for the mutants is identical within experimental error to that observed for the wild type enzyme. This observation is consistent with the conclusion that the ground state for the enzyme-carboxyphosphate-ADP complex in the mutants is destabilized relative to the same complex in the wild type enzyme. If the increase in the absolute rate of ATP hydrolysis was due to a stabilization of the transition state for carboxyphosphate hydrolysis then the positional isotope exchange rate relative to the chemical hydrolysis rate would have been expected to decrease in the mutants.

Contribution of histidine residues to the conformational stability of ribonuclease T1 and mutant Glu-58----Ala.

The pK values of the histidine residues in ribonuclease T1 (RNase T1) are unusually high: 7.8 (His-92), 7.9 (His-40), and 7.3 (His-27) [Inagaki et al. (1981) J. Biochem. 89, 1185-1195]. In the RNase T1 mutant Glu-58----Ala, the first two pK values are reduced to 7.4 (His-92) and 7.1 (His-40). These lower pKs were expected since His-92 (5.5 A) and His-40 (3.7 A) are in close proximity to Glu-58 at the active site. The conformational stability of RNase T1 increases by over 4 kcal/mol between pH 9 and 5, and this can be entirely accounted for by the greater affinity for protons by the His residues in the folded protein (average pK = 7.6) than in the unfolded protein (pk approximately 6.6). Thus, almost half of the net conformational stability of RNase T1 results from a difference between the pK values of the histidine residues in the folded and unfolded conformations. In the Glu-58----Ala mutant, the increase in stability between pH 9 and 5 is halved (approximately 2 kcal/mol), as expected on the basis of the lower pK values for the His residues in the folded protein (average pK = 7.1). As a consequence, RNase T1 is more stable than the mutant below pH 7.5, and less stable above pH 7.5. These results emphasize the importance of measuring the conformational stability as a function of pH when comparing proteins differing in structure.