Single-turnover Enzyme Research Articles

Single-Molecule Studies of Restriction Endonuclease Kinetics

Under optimal conditions, restriction endonucleases are capable of mediating remarkably specific DNA cleavage. This quality makes the restriction endonuclease an indispensible tool for genetic modification and manipulation. However, the mechanism by which restriction endonucleases effectively discriminate between their cognate site and other DNA sequences is not fully understood. Under certain conditions, many restriction endonucleases display “star activity” - relaxed specificity resulting in DNA cleavage at sequences that differ from their normal recognition sequence - but the mechanism by which specificity is relaxed is not fully understood. Although at least 600 of the almost 4000 restriction endonucleases that have been identified are commercially available in purified form, DNA cleavage kinetics of only a few of these enzymes have been studied in detail. We have developed a fluorescence-based approach with which we can track the progress of the cleavage reaction in real time, and simultaneously determine the values of the kinetic constants for a particular restriction endonuclease at a specific sequence. Modeling restriction endonuclease-mediated DNA cleavage as a Michaelis-Menten-like process, we expected reaction rates to display a hyperbolic dependence on substrate concentration, but our measurements deviate from this dependence, especially under conditions associated with increased star activity (such as low ionic strength). These observations suggest that substrate inhibition may be a part of the reaction mechanism under normal conditions, and that star activity may be a result of an increase in the population of this pathway. Using high density arrays of femtoliter-sized reaction vessels created by selectively etching bundled optical fibers, we can observe the cleavage activity of hundreds of individual restriction endonuclease molecules in solution. By characterizing the population distribution of single-enzyme turnover rates under a variety of conditions, we hope to gain insight into the reaction mechanisms of both specific cleavage and star activity.

Generalized Haldane equation and fluctuation theorem in the steady-state cycle kinetics of single enzymes

Enzyme kinetics are cyclic. We study a Markov renewal process model of single-enzyme turnover in nonequilibrium steady state (NESS) with sustained concentrations for substrates and products. We show that the forward and backward cycle times have identical nonexponential distributions: Theta + (t)=Theta_(t). This equation generalizes the Haldane relation in reversible enzyme kinetics. In terms of the probabilities for the forward (p+) and backward (p-) cycles, kBT ln(p+/p-) is shown to be the chemical driving force of the NESS, Delta mu. More interestingly, the moment generating function of the stochastic number of substrate cycle v(t), <e-lambda v(t)> , follows the fluctuation theorem in the form of Kurchan-Lebowitz-Spohn-type symmetry. When lambda=delta mu/kBT, we obtain the Jarzynski-Hatano-Sasa-type equality <e-v(t)Delta mu/kBT> identical with 1 for all t, where v Delta mu is the fluctuating chemical work done for sustaining the NESS. This theory suggests possible methods to experimentally determine the nonequilibrium driving force in situ from turnover data via single-molecule enzymology.

A direct, continuous, sensitive assay for protein disulphide-isomerase based on fluorescence self-quenching

PDI (protein disulphide-isomerase) activity is generally monitored by insulin turbidity assay or scrambled RNase assay, both of which are performed by UV-visible spectroscopy. In this paper, we present a sensitive fluorimetric assay for continuous determination of disulphide reduction activity of PDI. This assay utilizes the pseudo-substrate diabz-GSSG [where diabz stands for di-(o-aminobenzoyl)], which is formed by the reaction of isatoic anhydride with the two free N-terminal amino groups of GSSG. The proximity of two benzoyl groups leads to quenching of the diabz-GSSG fluorescence by approx. 50% in comparison with its non-disulphide-linked form, abz-GSH (where abz stands for o-aminobenzoyl). Therefore the PDI-dependent disulphide reduction can be monitored by the increase in fluorescence accompanying the loss of proximity-quenching upon conversion of diabz-GSSG into abz-GSH. The apparent K(m) of PDI for diabz-GSSG was estimated to be approx. 15 muM. Unlike the insulin turbidity assay and scrambled RNase assay, the diabz-GSSG-based assay was shown to be effective in determining a single turnover of enzyme in the absence of reducing agents with no appreciable blank rates. The assay is simple to perform and very sensitive, with an estimated detection limit of approx. 2.5 nM PDI, enabling its use for the determination of platelet surface PDI activity in crude sample preparations.

A snapshot of enzyme catalysis using electrospray ionization mass spectrometry.

Insights into the early molecular events involving protein-ligand/substrate interactions such as protein signaling and enzyme catalysis can be obtained by examining these processes on a very short, millisecond time scale. We have used time-resolved electrospray mass spectrometry to delineate the catalytic mechanism of a key enzyme in bacterial lipopolysaccharide biosynthesis, 3-deoxy-d-manno-2-octulosonate-8-phosphate synthase (KDO8PS). Direct real-time monitoring of the catalytic reaction under single enzyme turnover conditions reveals a novel hemiketal phosphate intermediate bound to the enzyme in a noncovalent complex that establishes the reaction pathway. This study illustrates the successful application of mass spectrometry to reveal transient biochemical processes and opens a new time domain that can provide detailed structural information of short-lived protein-ligand complexes.

Structural Basis for the Impaired Channeling and Allosteric Inter-subunit Communication in the βA169L/βC170W Mutant of Tryptophan Synthase

We determined the 2.25 A resolution crystal structure of the betaA169L/betaC170W mutant form of the tryptophan synthase alpha(2)beta(2) complex from Salmonella typhimurium complexed with the alpha-active site substrate analogue 5-fluoro-indole-propanol-phosphate to identify the structural basis for the changed kinetic properties of the mutant (Anderson, K. S., Kim, A. Y., Quillen, J. M., Sayers, E., Yang, X. J., and Miles, E. W. (1995) J. Biol. Chem. 270, 29936-29944). Comparison with the wild-type enzyme showed that the betaTrp(170) side chain occludes the tunnel connecting the alpha- and beta-active sites, explaining the accumulation of the intermediate indole during a single enzyme turnover. To prevent a steric clash between betaLeu(169) and betaGly(135), located in the beta-sheet of the COMM (communication) domain (betaGly(102)-betaGly(189)), the latter reorganizes. The changed COMM domain conformation results in a loss of the hydrogen bonding networks between the alpha- and beta-active sites, explaining the poor activation of the alpha-reaction upon formation of the aminoacrylate complex at the beta-active site. The 100-fold reduced affinity for serine seems to result from a movement of betaAsp(305) away from the beta-active site so that it cannot interact with the hydroxyl group of a pyridoxal phosphate-bound serine. The proposed structural dissection of the effects of each single mutation in the betaA169L/betaC170W mutant would explain the very different kinetics of this mutant and betaC170F.

Catalytic mechanism of scytalone dehydratase: site-directed mutagenisis, kinetic isotope effects, and alternate substrates.

On the basis of the X-ray crystal structure of scytalone dehydratase complexed with an active center inhibitor [Lundqvist, T., Rice, J., Hodge, C. N., Basarab, G. S., Pierce, J. and Lindqvist, Y. (1994) Structure (London) 2, 937-944], eight active-site residues were mutated to examine their roles in the catalytic mechanism. All but one residue (Lys73, a potential base in an anti elimination mechanism) were found to be important to catalysis or substrate binding. Steady-state kinetic parameters for the mutants support the native roles for the residues (Asn131, Asp31, His85, His110, Ser129, Tyr30, and Tyr50) within a syn elimination mechanism. Relative substrate specificities for the two physiological substrates, scytalone and veremelone, versus a Ser129 mutant help assign the orientation of the substrates within the active site. His85Asn was the most damaging mutation to catalysis consistent with its native roles as a general base and a general acid in a syn elimination. The additive effect of Tyr30Phe and Tyr50Phe mutations in the double mutant is consistent with their roles in protonating the substrate's carbonyl through a water molecule. Studies on a synthetic substrate, which has an anomeric carbon atom which can better stabilize a carbocation than the physiological substrate (vermelone), suggest that His110Asn prefers this substrate over vermelone in order to balance the mutation-imposed weakness in promoting the elimination of hydroxide from substrates. All mutant enzymes bound a potent active-site inhibitor in near 1:1 stoichiometry, thereby supporting their active-site integrity. An X-ray crystal structure of the Tyr50Phe mutant indicated that both active-site waters were retained, likely accounting for its residual catalytic activity. Steady-state kinetic parameters with deuterated scytalone gave kinetic isotope effects of 2.7 on kcat and 4.2 on kcat/Km, suggesting that steps after dehydration partially limit kcat. Pre-steady-state measurements of a single-enzyme turnover with scytalone gave a rate that was 6-fold larger than kcat. kcat/Km with scytalone has a pKa of 7.9 similar to the pKa value for the ionization of the substrate's C6 phenolic hydroxyl, whereas kcat was unaffected by pH, indicating that the anionic form of scytalone does not bind well to enzyme. With an alternate substrate having a pKa above 11, kcat/Km had a pKa of 9.3 likely due to the ionization of Tyr50. The non-enzyme-catalyzed rate of dehydration of scytalone was nearly a billion-fold slower than the enzyme-catalyzed rate at pH 7.0 and 25 degrees C. The non-enzyme-catalyzed rate of dehydration of scytalone had a deuterium kinetic isotope effect of 1.2 at pH 7.0 and 25 degrees C, and scytalone incorporated deuterium from D2O in the C2 position about 70-fold more rapidly than the dehydration rate. Thus, scytalone dehydrates through an E1cb mechanism off the enzyme.

Involvement of phenylalanine 272 of DNA polymerase beta in discriminating between correct and incorrect deoxynucleoside triphosphates.

DNA polymerase beta is a small monomeric polymerase that participates in base excision repair and meiosis [Sobol, R., et al. (1996) Nature 379, 183-186; Plug, A., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1327-1331]. A DNA polymerase beta mutator mutant, F272L, was identified by an in vivo genetic screen [Washington, S., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1321-1326]. Residue 272 is located within the deoxynucleoside triphosphate (dNTP) binding pocket of DNA polymerase beta according to the known DNA polymerase beta crystal structures [Pelletier, H., et al. (1994) Science 264, 1891-1893; Sawaya, M., et al. (1997) Biochemistry 36, 11205-11215]. The F272L mutant produces errors at a frequency 10-fold higher than that of wild type in vivo and in the in vitro HSV-tk gap-filling assay. F272L shows an increase in the frequency of both base substitution mutations and frameshift mutations. Single-enzyme turnover studies of misincorporation by wild type and F272L DNA polymerase beta demonstrate that there is a 4-fold decrease in fidelity of the mutant as compared to that of the wild type enzyme for a G:A mismatch. The decreased fidelity is due primarily to decreased discrimination between the correct and incorrect dNTP during ground-state binding. These results suggest that the phenylalanine 272 residue is critical for maintaining fidelity during the binding of the dNTP.

Catalytic mechanism of Kdo8P synthase: transient kinetic studies and evaluation of a putative reaction intermediate.

The mechanistic pathway for the reaction catalyzed by Kdo8P synthase has been investigated, and the cyclic bisphosphate 2 has been examined as a putative reaction intermediate. Two parallel approaches were used: (1) chemical synthesis of 2 and evaluation as an alternate substrate for the enzyme and (2) transient kinetic studies using rapid chemical quench methodology to provide direct observation and characterization of putative intermediate(s) during enzyme catalysis. The putative cyclic bisphosphate intermediate 2, possessing the stereochemistry of the beta-pyranose form, was synthesized and evaluated as a substrate and as an inhibitor of Kdo8P synthase. The substrate activity was examined by monitoring the release of anomeric phosphate over time using proton-decoupled 31P NMR spectroscopy. A very similar time course for the formation of inorganic phosphate was found in each experiment and the corresponding control experiment; i.e., no enzyme-catalyzed acceleration in the anomeric phosphate hydrolysis was detected. It was found however that 2 binds to the enzyme and is a competitive inhibitor with respect to phosphoenolpyruvate binding, having a Ki value of 35 microM. In a parallel study, we have performed single-turnover rapid chemical quench experiments to examine both the forward and reverse directions to identify a putative enzyme intermediate(s). Our results clearly demonstrate that the cyclic bisphosphate intermediate 2 does not accumulate under single-enzyme turnover conditions. This observation, coupled with the results obtained through the evaluation of synthetic 2 as a substrate, strongly suggests that the Kdo8P synthase catalytic pathway does not involve the formation of 2 as a reaction intermediate. Taken together, these combined results support the original hypothesis [Hedstrom, L., and Abeles, R. H. (1988) Biochem. Biophys. Res. Commun. 157, 816-820], which suggests a reaction pathway involving an acyclic bisphosphate intermediate 1.

Kinetic Characterization of Channel Impaired Mutants of Tryptophan Synthase

Tryptophan synthase, an alpha 2 beta 2 tetrameric complex, is a classic example of an enzyme that is thought to "channel" a metabolic intermediate (indole) from the active site of the alpha subunit to the active site of the beta subunit. The solution of the three-dimensional structure of the enzyme from Salmonella typhimurium provided physical evidence for a 25-A hydrophobic tunnel which connects the alpha and beta active sites (Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., and Davies, D. R. (1988) J. Biol. Chem. 263, 17857-17871). Using rapid reaction kinetics, we have previously established that indole is indeed channeled and have identified three essential kinetic features which govern efficient channeling. In the current study we have probed the necessity of these features by using site-directed mutagenesis to alter these requirements. We now report the kinetic characterization of two mutants which contain substitutions to block or restrict the tunnel (beta C170F and beta C170W). Preliminary kinetic and structural evidence of a restricted tunnel in the beta C170W has been provided (Schlichting, I., Yang, X. W., Miles, E. W., Kim, A. Y., and Anderson, K. S. (1994) J. Biol. Chem. 269, 26591-26593). The rapid kinetic analysis of these mutant proteins shows that these mutations interfere with efficient channeling of the indole metabolite such that indole can be observed in single enzyme turnover of the physiologically relevant alpha beta reaction. In addition, the beta C170W mutant appears to be impaired in alpha beta intersubunit communication.

Reaction Mechanism of L-2-Haloacid Dehalogenase of Pseudomonas sp. YL: IDENTIFICATION OF Asp10 AS THE ACTIVE SITE NUCLEOPHILE BY 18O INCORPORATION EXPERIMENTS

L-2-Haloacid dehalogenase (EC 3.8.1.2) catalyzes the hydrolytic dehalogenation of L-2-haloacids to produce the corresponding D-2-hydroxy acids. We have analyzed the reaction mechanism of the enzyme from Pseudomonas sp. YL and found that Asp10 is the active site nucleophile. When the multiple turnover enzyme reaction was carried out in H2(18)O with L-2-chloropropionate as a substrate, lactate produced was labeled with 18O. However, when the single turnover enzyme reaction was carried out by use of a large excess of the enzyme, the product was not labeled. This suggests that an oxygen atom of the solvent water is first incorporated into the enzyme and then transferred to the product. After the multiple turnover reaction in H2(18)O, the enzyme was digested with lysyl endopeptidase, and the molecular masses of the peptide fragments formed were measured by an ionspray mass spectrometer. Two 18O atoms were shown to be incorporated into a hexapeptide, Gly6-Lys11. Tandem mass spectrometric analysis of this peptide revealed that Asp10 was labeled with two 18O atoms. Our previous site-directed mutagenesis experiment showed that the replacement of Asp10 led to a significant loss in the enzyme activity. These results indicate that Asp10 acts as a nucleophile on the alpha-carbon of the substrate leading to the formation of an ester intermediate, which is hydrolyzed by nucleophilic attack of a water molecule on the carbonyl carbon atom.

Structural and kinetic analysis of a channel-impaired mutant of tryptophan synthase.

Substrate channeling is a process by which two sequential enzymes interact to transfer a metabolite (or intermediate) from one enzyme active site to the next without allowing free diffusion of the metabolite. Channeling is thought to play an important role in metabolic regulation and cellular modulation of enzymatic activities. Although there are numerous examples of sequential enzyme pairs in glycolysis and other biosynthetic pathways that are thought to exhibit channeling, this is as yet controversial. Tryptophan synthase is considered the best example for an enzyme displaying channeling behavior between subunits. Tryptophan synthase is an alpha 2 beta 2 tetrameric enzyme complex, which catalyzes the last two steps in the biosynthesis of L-tryptophan. The alpha subunit catalyzes the cleavage of indole-3-glycerol phosphate to indole and glyceraldehyde-3-phosphate; the beta subunit catalyzes the condensation of indole with serine to form tryptophan, in a reaction mediated by pyridoxal phosphate. The inability to trap free indole in the steady-state reaction and analysis of the kinetics of single turnover reactions have led to the postulate that indole may pass directly from the alpha to the beta site without diffusion through solution (Demoss, J. A. (1962) Biochim. Biophys. Acta 62, 279-293; Matchett, W. M. (1974) J. Biol. Chem. 249, 4041-4049). The crystal structure of tryptophan synthase from Salmonella typhimurium has provided additional support for substrate channeling by elucidating a 25-A hydrophobic tunnel connecting the two catalytic sites (Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., and Davies, D. R. (1988) J. Biol. Chem. 263, 17857-17871). The structure suggests that mutation of a residue lining the tunnel to a more bulky residue might impede or block the passage of indole during catalysis thus enabling detection of indole during a single enzyme turnover. A mutant of tryptophan synthase has been prepared in which one of the residues lining the tunnel, beta Cys-170, has been replaced with a bulkier tryptophan residue. Kinetic and structural analyses of the beta C170W mutant by rapid chemical quench methods and x-ray crystallographic analysis show both the transient formation of indole and the obstruction of the tunnel, thus providing direct evidence for the substrate channeling mechanism.

Mechanism of action of beta-oxoacyl-CoA thiolase from rat liver cytosol. Direct evidence for the order of addition of the two acetyl-CoA molecules during the formation of acetoacetyl-CoA.

Single-turnover enzyme reactions were employed with beta-oxoacyl-CoA thiolase purified from rat liver cytosol to determine the order of binding of the two acetyl-CoA molecules to the enzyme during the formation of acetoacetyl-CoA. Equimolar quantities of [1-14C]acetyl-CoA and enzyme were mixed initially in a rapid mixing device and the reaction was quenched by addition of an excess of unlabelled acetyl-CoA. Degradation of the resulting acetoacetyl-CoA revealed that the larger proportion of the radioactivity was in C-3. In the converse experiment, in which unlabelled acetyl-CoA was mixed with enzyme and the reaction was quenched with [1-14C]acetyl-CoA, radioactivity was incorporated preferentially into C-1. Similar results were obtained when [14C]acetyl-enzyme complex isolated by gel filtration was reacted with unlabelled acetyl-CoA, the radioactivity appearing largely in C-3. These findings lead to the conclusion that of the two molecules of acetyl-CoA that are bound by the enzyme and converted into acetoacetyl-CoA, it is the one giving rise to C-3 and -4 that is bound initially to the enzyme in the form of the acetyl-enzyme intermediate complex.

Subzero temperature studies of microsomol cytochrome P-450 : O-Dealkylation of 7-ethoxycoumarin coupled to single turnover

We reported with intact microsomes the formation and partial stabilization of a ferrous-oxy intermediate of cytochrome P-450 in fluid mixed solvents at subzero temperature [ 11. The data compare well with those from stopped flow measurements on purified cytochrome above O’C [2] and steady state recordings on intact microsomes [3]. The subzero temperature experiments offered two advantages, particularly with intact microsomes: (1) Uncoupling of the oxygen reaction from the other steps of the cycle; (2) Therefore single turnover of enzyme since the first electron is blocked at 2 -20°C [4,5]. The decomposition of this ferrous-oxy compound was also shown to be accompanied by the discharge of possible ‘leaks’ of oxidizing species, indirectly detected by the oxidative luminescence of luminol [S]. Here we use the same temperature programme to show that enzymatic U-dealkylation of the substrate 7ethoxycoumarin occurs during the single redox cycle of cytochrome P-450. This substrate was mainly chosen for the easy fluorometric detection of its product 7-hydroxycoumarin (umbelliferone, 7-OH coumarin) [6].

Subunit structure of Mycobacterium smegmatis fatty acid synthetase. Evidence for identical multifunctional polypeptide chains.

Fatty acid synthetase from Mycobacterium smegmatis has been purified to near homogeneity as judged by a variety of electrophoretic criteria under both native and dissociating conditions. A single protein band was obtained on gel electrophoresis in sodium dodecyl sulfate or 8 M urea at various pH values and on isoelectric focusing in 8 M urea. A subunit molecular weight of about 290,000 was found by polyacrylamide gel electrophoresis in sodium dodecyl sulfate or by sedimentation equilibrium ultracentrifugation in 6 M guanidine HCl. Quantitative Quantitative determination of pantetheine, of flavin, and of the number of fatty acids synthesized during a single enzyme turnover all yield values corresponding to a stoichiometry of about 1 mol per mol of subunit, providing strong evidence that M. smegmatis fatty acid synthetase is an oligomer of identical, multifunctional polypeptide chains.

Single-turnover enzyme kinetics: The evaluation of rate constants from a single kinetic experiment

1. 1. Chemical species concentrations have been represented in terms of both power, and asymptotic series expansions (in powers of time and time −1, respectively) for the one-intermediate single-turnover enzyme system: ▪ 2. 2. Evaluation of the rate constants k 1, k −1, and k 2 from a single kinetic experiment has been considered for the two cases: (a) When [ E] alone can be monitored. (b) When [ E] and [ ES] can be monitored. 3. 3. The validity of the techniques proposed have been investigated using computer simulation methods.