PAR对氨基酰化酶不可逆抑制动力学研究

本文将邹氏的在酶的活性修饰剂存在下的底物反应动力学理论应用于氨基酰化酶被金属螯合剂PAR脱锌而失活的动力学研究。通过对不同浓度的PAR存在下底物反应过程和含有PAR的不同浓度的底物中酶促反应的分析,讨论了PAR对氨基酰化酶的脱锌机制。这一过程很可能按如下机制进行:首先,PAR与酶分子活性部位的锌结合,形成一复合物,这一步是较快的反应,然后发生一个可逆的构象变化,最后是不可逆的去锌步骤。锌的存在显然稳定了酶活性部位的构象,而这正是酶活性所必需的。     

Kinetics of inactivation of green crab (Scylla Serrata) alkaline phosphatase during removal of zinc ions by ethylenediaminetetraacetic acid disodium

Green crab (Scylla Serrata) alkaline phosphatase (EC 3.1.3.1.) is a metalloenzyme, the each active site in which contains a tight cluster of two zinc ions and one magnesium ion. The kinetic theory of the substrate reaction during irreversible inhibition of enzyme activity previously described by Tsou has been applied to a study on the kinetics of the course of inactivation of the enzyme by ethylenediaminetetraacetic acid disodium (EDTA). The kinetics of the substrate reaction with different concentrations of the substrate p-nitrophenyl phosphate (PNPP) and inactivator EDTA suggested a complexing mechanism for inactivation by, and substrate competition with, EDTA at the active site. The inactivation kinetics are single phasic, showing the initial formation of an enzyme-EDTA complex is a relatively rapid reaction, followed a slow inactivation step that probably involves a conformational change of the enzyme. Zinc ions are finally removed from the enzyme. The presence of metal ions apparently stabilizes an active-site conformation required for enzyme activity.     

Kinetics of inactivation of Ulva pertusa Kjellm alkaline phosphatase by ethylenediaminetetraacetic acid disodium

Ulva pertusa Kjellm alkaline phosphatase (EC 3.3.3.1) is a metalloenzyme, the active site of which contains a tight cluster of two zinc ions and one magnesium ion. The kinetic theory described by Tsou of the substrate reaction during irreversible inhibition of enzyme activity has been employed to study the kinetics of the course of inactivation of the enzyme by EDTA. The kinetics of the substrate reaction at different concentrations of the substrate p-nitrophenyl phosphate (PNPP) and inactivator EDTA indicated a complexing mechanism for inactivation by, and substrate competition with, EDTA at the active site. The inactivation kinetics are single phasic, showing that the initial formation of an enzyme-EDTA complex is a relative rapid reaction, following by a slow inactivation step that probably involves a conformational change of the enzyme. The presence of Zn2+ apparently stabilizes an active-site conformation required for enzyme activity.     

Hysteretic enzyme response induced by inhibitory antibodies against human leukocyte elastase

Polyclonal antibodies raised in rabbits against human leukocyte elastase contained two distinct populations of enzyme-inhibiting immunoglobulins. The enzyme-catalyzed reaction in the presence of antibodies (both IgG or monovalent Fab fragments) showed a transient state lasting up to several minutes depending on the inhibitor and substrate concentrations, which was followed by a linear steady-state. The transient was a concave upward or concave downward lag phase depending on whether the enzyme had been preincubated with the antibodies or not, respectively. The kinetic analysis of reaction progress curves showed that both antibody populations were slow inhibitors, which completely and reversibly excluded the substrate from binding to the enzyme. For both antibody populations, the formation of the enzyme-inhibitor complex was characterized by an initial rapid interaction followed by a slow isomerization to a catalytically inactive complex. The apparent pseudo first-order rate constant of the transient slow phase was a hyperbolic function of the inhibitor concentration for both antibodies, from which relevant kinetic constants and the half times for enzyme inactivation could be calculated. For instance, with a total antibody concentration of 1 mg/ml (as IgG), leukocyte elastase was inactivated with t1/2 = 0.31s and 24.8s by the faster and the slower of the two antibodies, respectively. It is suggested that the hysteretic response of the enzyme to the inhibitory action of its antibodies may be due to a kind of memory of the antibody molecule for a special inactive enzyme conformation resulting from inhibition by proteinase inhibitors during the immunization procedure. In turn, the purified antibodies would be able to reversibly induce a slow transition of the enzyme molecule from an active to a substrate-excluding conformation ("induced misfit").     

Study on the role of SH-groups in the activity of muscle pyruvate dehydrogenase

The kinetics of inactivation of the pyruvate dehydrogenase component of the pigeon breast muscle pyruvate dehydrogenase complex in the presence of 5,5'-dithiobis (2-nitrobenzoate) is biphasic. The rate constants for the fast and slow phases of the inactivation reaction are close to those for modification of two classes of SH-groups differing in their reactivities towards the inhibitor. The reaction order with respect to the inhibitor concentration suggests that the two distinct SH-groups are essential for the enzyme activity. Modification of these SH-groups results in inhibition of the overall activity of the pyruvate dehydrogenase complex and of the 2-hydroxyethyl thiamine pyrophosphate - acceptor oxidoreductase activity of its decarboxylating component. Thiamine pyrophosphate exerts a protective effect on the enzyme only at the slow phase of the enzyme inactivation and SH-modification. As a result of interaction between the holoenzyme and pyruvate (or apoenzyme and 2-hydroxyethyl thiamine pyrophosphate) the rate of the enzyme inactivation is increased. This is associated with masking of non-essential SH-groups and with an increase of the accessibility of two essential SH-groups to the inhibitor. The data obtained suggest the interrelationship between the essential SH-groups and the 2-hydroxyethyl thiamine pyrophosphate-acceptor oxidoreductase activity of pyruvate dehydrogenase.     

Stabilization of the enzyme--substrate complex of the mutant Asp-67Asn inorganic pyrophosphatase from Escherichia coli by fluoride ions

Magnesium-supported PPi hydrolysis by the mutant Asp-67Asn E. coli pyrophosphatase at saturating PPi and metal-activator concentrations in the presence of NaF is followed by a gradual decrease in the initial rate of PPi hydrolysis. The reaction occurs in two steps: first a complex containing enzyme, pyrophosphate, magnesium, and fluoride ions is immediately formed, then its conformation changes slowly. This enzyme--substrate complex stabilized by fluoride is partially active and can be isolated by the removal of excess fluoride by gel-filtration.     

Catalytic versatility of Bacillus pumilus beta-xylosidase: glycosyl transfer and hydrolysis promoted with alpha- and beta-D-xylosyl fluoride

Bacillus pumilus beta-xylosidase, an enzyme considered restricted to hydrolyzing a narrow range of beta-D-xylosidic substrates with inversion of configuration, was found to catalyze different stereochemical, essentially irreversible, glycosylation reactions with alpha- and beta-D-xylopyranosyl fluoride. The enzyme promoted the hydrolysis of beta-D-xylopyranosyl fluoride at a high rate, V = 6.25 mumol min-1 mg-1 at 0 degrees C, in a reaction that obeyed Michaelis-Menten kinetics. In contrast, its action upon alpha-D-xylopyranosyl fluoride was slow and characterized by an unusual relation between the rate of fluoride release and the substrate concentration, suggesting the possible need for two substrate molecules to be bound at the active center in order for reaction to occur. Moreover, 1H NMR spectra of a digest of alpha-D-xylosyl fluoride showed the substrate to be specifically converted to alpha-D-xylose by the enzyme. The observed retention of configuration is not consistent with direct hydrolysis by this "inverting" enzyme but is strongly indicative of the occurrence of two successive inverting reactions: xylosyl transfer from alpha-D-xylosyl fluoride to form a beta-D-xylosidic product, followed by hydrolysis of the latter to produce alpha-D-xylose. The transient intermediate product formed enzymically from alpha-D-xylosyl fluoride in the presence of [14C]xylose was isolated and shown by its specific radioactivity and 1H NMR spectrum as well as by methylation and enzymic analyses to be 4-O-beta-D-xylopyranosyl-D-xylopyranose containing one [14C]xylose residue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chemical modifications of histidyl and tyrosyl residues of inorganic pyrophosphatase from Escherichia coli

Chemical modifications by photooxidation in the presence of rose bengal (RB) and with tetranitromethane (TNM) were carried out to elucidate the amino acid residues involved in the active site of inorganic pyrophosphatase (pyrophosphate phosphohydrolase) [EC 3.6.1.1] from Escherichia coli Q13. The photooxidation caused almost complete inactivation, which followed pseudo-first-order kinetics depending on pH and concentration of RB. The presence of Mg2+ or complex between Mg2+ and substrate or substrate analogues, imidodiphosphate and sodium methylenediphosphate, gave partial protection against the photoinactivation, whereas the substrate alone showed no protective effect. The enzyme was almost completely inactivated by chemical modification with TNM, depending upon the concentration of TNM. The amino acid analyses and enzyme activity measurements revealed that 2 histidyl residues among 5 photooxidized residues and 2 tyrosyl residues per subunit were essential for the enzyme activity. The circular dichroism (CD) spectra in the far ultraviolet region showed no significant alteration during these two modifications, indicating that the polypeptide chain backbone of the enzyme remained unaltered. However, the modifications altered considerably the CD bands in the near ultraviolet region and the fluorescence spectra, indicating that subtle change in conformation had occurred in the vicinity of the active site in the enzyme molecule. These results strongly suggest that histidyl and tyrosyl residues may be involved in the active site or be located in the vicinity of the active site and seem to participate in the mechanism of stability against heat inactivation.     

Functional role of histidine residues of alpha-ketoglutarate dehydrogenase

The protective effect of alpha-ketoglutarate dehydrogenase substrate and its analogs on the enzyme inactivation by diethylpyrocarbonate was studied. The values of true rate constants for diethylpyrocarbonate-induced inactivation and the Kd values for the enzyme complexes with ligands were determined. A comparison of Kd values for a number of ligands suggests that the histidine residue of the enzyme active center interacts with the alpha-keto group of the substrate. A mechanism of this histidine residue involvement in the catalytic act is proposed. According to this mechanism, the imidazole ring of histidine which is responsible for the substrate activation causes a simultaneous formation of a catalytically active form of the coenzyme--thiamine pyrophosphate ilide. It is assumed that the lower (as compared with the enzyme-substrate complexes) values of rate constants of inactivation by diethylpyrocarbonate for alpha-ketoglutarate dehydrogenase complexes with succinate, glutarate, and oxaloacetate are due to additional protonation of the histidine residue, eventually resulting in the blocking of the analogs interaction with the coenzyme.     

The substrate-mediated inactivation of the pyruvate dehydrogenase component of the pigeon breast muscle pyruvate dehydrogenase complex

Incubation of the pyruvate dehydrogenase component isolated from the pigeon breast muscle pyruvate dehydrogenase complex with Mg2+, thiamine pyrophosphate and low concentrations of pyruvic acid in the absence of electron acceptors results in irreversible time-dependent inactivation of the enzyme. The rate of the enzyme inactivation is markedly decreased in the presence of high concentrations of pyruvate; in this case acetoin and acetolactate are detected in the reaction mixture. The enzyme activity is stabilized when the artificial electron acceptor, 2,6-dichlorophenolindophenol, is present in the reaction mixture. The substrate-mediated inactivation of the enzyme is accompanied by incorporation of the 2-[14C]-substrate fragment and labelled thiamine pyrophosphate into the protein fraction. The enzyme reactivation by neutral hydroxylamine and the protective effect of dithiothreitol suggest that the SH-group(s) may be involved in the substrate-mediated inactivation of pyruvate dehydrogenase.     

Two-stage mechanism of the fluoride inhibition of inorganic pyrophosphatase using the fluoride ion

Some kinetic and spectral approaches have been used to study the interactions in the enzyme-Mg2+-F--pyrophosphate (or imidodiphosphate, a non-hydrolyzeable pyrophosphate analog) system underlying the mechanism of yeast inorganic pyrophosphatase inhibition by fluoride. The continuous curves of the enzymatic reaction were obtained with an automatic phosphate analyzer operating on the time scale of seconds. Increasing concentrations of NaF caused an increase in the inactivation rate constant to a constant level of 5.3 min-1 for PPi (pH 6.2-7.2) and 3.9 min-1 for imidodiphosphate, (pH 7.2). At a saturating fluoride concentration, the initial rate of PPi hydrolysis dropped to 10%. NaF and imidodiphosphate changed the protein spectrum at 270-310 nm and strengthened the binding of each other to the protein. The binding of F- required a Mg2+-binding site with Kd = 0.15 mM being filled in. The free enzyme and its Ca2+ complex did not bind F-. The experimental results indicate that pyrophosphatase inhibition by fluoride occurs in two steps. The inhibitor adds first to the Mg2+ ion on the enzyme in a readily reversible reaction causing a 90% decrease of the catalytic activity. Thereafter, a slow isomerization of the enzymesubstrate complex takes place, resulting in a complete loss of activity.     

Product distribution and pre-steady-state kinetic analysis of Escherichia coli undecaprenyl pyrophosphate synthase reaction

Undecaprenyl pyrophosphate synthase (UPPs) catalyzes the condensation of eight molecules of isopentenyl pyrophosphate (IPP) with farnesyl pyrophosphate (FPP) to generate C(55) undecaprenyl pyrophosphate. We investigated the kinetics and mechanism of this reaction pathway using Escherichia coli UPPs. With a variety of different ratios of enzyme to substrate and FPP to IPP in the presence or absence of Triton, different product distributions were found. In the presence of excess FPP, the intermediates (C(25)-C(50)) accumulated. Under a condition with enzyme and FPP in excess of IPP, instead of C(20)-geranylgeranyl pyrophosphate, C(20), C(25), and C(30) were the major products. The UPPs steady-state k(cat) value (2.5 s(-1)) in the presence of 0.1% Triton was 190-fold larger than in the absence of Triton (0.013 s(-1)). The k(cat) value matched the rate constant of each IPP condensation obtained from the enzyme single-turnover experiments. This suggested that the IPP condensation rather than product release was the rate-limiting step in the presence of Triton. In the absence of Triton, the intermediates formed and disappeared in a similar manner under enzyme single turnover in contrast to the slow steady-state rate, which indicated a step after product generation was rate limiting. This was further supported by a burst product formation. Judging from the accumulation level of C(55), C(60), and C(65), their dissociation from the enzyme cannot be too slow and an even slower enzyme conformational change with a rate of 0.001 s(-1) might govern the UPPs reaction rate under the steady-state condition in the absence of Triton.     

Fluoride effects along the reaction pathway of pyrophosphatase: evidence for a second enzyme.pyrophosphate intermediate

The fluoride ion is a potent and specific inhibitor of cytoplasmic pyrophosphatase (PPase). Fluoride action on yeast PPase during PP(i) hydrolysis involves rapid and slow phases, the latter being only slowly reversible [Smirnova, I. N., and Baykov, A. A. (1983) Biokhimiya 48, 1643-1653]. A similar behavior is observed during yeast PPase catalyzed PP(i) synthesis. The amount of enzyme.PP(i) complex formed from solution P(i) exhibits a rapid drop upon addition of fluoride, followed, at pH 7.2, by a slow increase to nearly 100% of the total enzyme. The slow reaction results in enzyme inactivation, which is not immediately reversed by dilution. These data show that fluoride binds to an enzyme.PP(i) intermediate during the slow phase and to an enzyme.P(i) intermediate during the rapid phase of the inhibition. In Escherichia coli PPase, the enzyme.PP(i) intermediate binds F(-) rapidly, explaining the lack of time dependence in the inhibition of this enzyme. The enzyme.PP(i) intermediate formed during PP(i) hydrolysis binds fluoride much faster (yeast PPase) or tighter (E. coli PPase) than the similar complex existing at equilibrium with P(i). It is concluded that PPase catalysis involves two enzyme.PP(i) intermediates, of which only one (immediately following PP(i) addition and predominating at acidic pH) can bind fluoride. Simulation experiments have indicated that interconversion of the enzyme.PP(i) intermediates is a partially rate-limiting step in the direction of hydrolysis and an exclusively rate-limiting step in the direction of synthesis.     

Kinetics of inhibition of alkaline phosphatase from green crab (Scylla serrata) by N-bromosuccinimide

The inactivation of alkaline phosphatase from green crab (Scylla serrata) by N-bromosuccinimide has been studied using the kinetic method of the substrate reaction during modification of enzyme activity previously described by Tsou [(1988),Adv. Enzymol. Related Areas Mol. Biol. 61, 381–436]. The results show that inactivation of the enzyme is a slow, reversible reaction. The microscopic rate constants for the reaction of the inactivator with free enzyme and the enzyme-substrate complex were determined. Comparison of these rate constants indicates that the presence of substrate offers marked protection of this enzyme against inactivation by N-bromosuccinimide. The above results suggest that the tryptophan residue is essential for activity and is situated at the active site of the enzyme.     

The molecular weight and thiol residues of acetyl-coenzyme A synthetase from ox heart mitochondria

1. A constant molecular weight of 57000 was obtained by gel filtration of highly purified acetyl-CoA synthetase over a 1000-fold range of enzyme concentrations. The amino acid analysis is reported. 2. With native enzyme at 20 degrees C the relatively rapid reaction of four thiol residues with p-hydroxymercuribenzoate caused an immediate inhibition reversible by either CoA or mercaptoethanol. Other substrates did not protect against this rapid inhibition. 3. The much slower reaction of the remaining four thiol residues was independent of the concentration of the mercurial, first-order with respect to enzyme, and had a large energy of activation (+136kJ/mol), suggesting that a conformation change in the protein was rate-limiting. This slow phase of the reaction was accompanied by an irreversible inactivation of the enzyme. 4. The effects of substrates on this irreversible inactivation at pH7.0 in 5 mm-MgCl(2) indicated strong binding of ATP and pyrophosphate by the enzyme (concentrations for half-maximal effects, K((1/2)), were <30mum and <10mum respectively) and weaker binding of acetyl-CoA (K((1/2)) about 1 mm), AMP (K((1/2)) about 2mm) and acetate. In the presence of acetate, MgCl(2) and p-hydroxymercuribenzoate, titration of the enzyme with ATP revealed at least two ATP binding sites/mol. 5. The experiments suggest that reaction of the thiol residues with mercurial causes loss of enzymic activity by altering the structure of the enzyme, rather than that the thiol residues play a direct role in the catalysis.     

6-diazo-5-oxo-L-norleucine and azaserine as affinity inhibitors of glutamin(asparagin)ase

Incubation of homogeneous glutamin(asparagin)ase from Pseudomonas aurantiaca with 6-diazo-5-oxo-L-norleucine (DON) and azaserine leads to an almost complete inactivation of the enzyme. The inactivation process in both cases involves the step of reversible binding of the enzyme with the inhibitor into a complex and subsequent modification of the enzyme within this complex. The data on saturation of the enzyme by low concentrations of inhibitors, the protective effect of substrate and its analogs as well as of the competitive inhibitor and product of the enzymatic reaction, L-aspartate, suggest that the modification of functional groups takes place in the enzyme active site. The presence of essential threonine hydroxyl groups in/or near the enzyme active site is surmised.     

Kinetics of inhibition of alkaline phosphatase from green crab (Scylla serrata) by N-bromosuccinimide

The inactivation of alkaline phosphatase from green crab (Scylla serrata) by N-bromosuccinimide has been studied using the kinetic method of the substrate reaction during modification of enzyme activity previously described by Tsou [(1988),Adv. Enzymol. Related Areas Mol. Biol. 61, 381–436]. The results show that inactivation of the enzyme is a slow, reversible reaction. The microscopic rate constants for the reaction of the inactivator with free enzyme and the enzyme-substrate complex were determined. Comparison of these rate constants indicates that the presence of substrate offers marked protection of this enzyme against inactivation by N-bromosuccinimide. The above results suggest that the tryptophan residue is essential for activity and is situated at the active site of the enzyme.Abbreviations ALP alkaline phosphatase - PNPP p-nitrophenyl phosphate - NBS N-bromosuccinimide     

Inactivation of gamma-glutamyl transpeptidase by phenylmethanesulfonyl fluoride, a specific inactivator of serine enzymes.

Rat kidney γ-glutamyl transpeptidase was found to be inactivated by phenylmethanesulfonyl fluoride, a specific inactivator of serine enzymes. The inactivation occurred only in the presence of maleate which was known to enhance the hydrolytic activity of this enzyme. The concentration of phenylmethanesulfonyl fluoride giving a half maximum rate of inactivation was 1.1 mM. The presence of S-methyl glutathione, a substrate for this enzyme, prevented the inactivation in a competitive fashion. These findings indicate that phenylmethanesulfonyl fluoride acts as an active site directed reagent for γ-glutamyl transpeptidase. A possible identity of the labeled site with that for 6-diazo-5-oxo-L-norleucine, another affinity label for this enzyme, was discussed.     

Fluoride inhibition of inorganic pyrophosphatase. IV. Evidence for metal participation in the active center and a four-site model of metal effect on catalysis.

Atomic spectroscopy of native yeast inorganic pyrophosphatase (pyrophosphate phosphohydrolase, EC 3.6.1.1) after gel filtration showed that it only binds activating Mg2% in an easily dissociable manner. Formation of a covalent intermediate between the enzyme and an entire substrate molecular in the presence of fluoride, however, dramatically strengthened the binding of two Mg2+ per subunit and eliminated at neutral pH the effect of added metals on protein fluorescence but not on the absorption spectrum, suggesting that different mental binding sites influence the two spectra. This conclusion was confirmed by spectra studied on native enzyme. A third, low-affinity site for Mg2+ was found on the enzyme pH greater than 8. A model of enzyme-substrate-metal interactions was proposed, according to which the fluorescence-controlling site belongs to the active center and substrate can only be bound to it as a 1 : 1 complex with metals.     

Insight into the activation mechanism of Escherichia coli octaprenyl pyrophosphate synthase derived from pre-steady-state kinetic analysis

Octaprenyl pyrophosphate synthase (OPPs) catalyzes the sequential condensation of five molecules of isopentenyl pyrophosphate with farnesyl pyrophosphate to generate all-trans C40-octaprenyl pyrophosphate, which constitutes the side chain of ubiquinone. Due to the slow product release, a long-chain polyprenyl pyrophosphate synthase often requires detergent or another factor for optimal activity. Our previous studies in examining the activity enhancement of Escherichia coli undecaprenyl pyrophosphate synthase have demonstrated a switch of the rate-determining step from product release to isopentenyl pyrophosphate (IPP) condensation reaction in the presence of Triton [12]. In order to understand the mechanism of enzyme activation for E. coli OPPs, a single-turnover reaction was performed and the measured IPP condensation rate (2 s(-1)) was 100 times larger than the steady-state rate (0.02 s(-1)). The high molecular weight fractions and Triton could accelerate the steady-state rate by 3-fold (0.06 s(-1)) but insufficient to cause full activation (100-fold). A burst product formation was observed in enzyme multiple turnovers indicating a slow product release.