OPTA对乳酸脱氢酶的抑制动力学

邹承鲁建立的酶活性不可逆改变动力学理论已为实验所验证,它不仅适用于单底物酶的抑制和激活的动力学研究,而且也适用于双底物酶反应系统.但在双底物酶反应系统中,底物和酶的结合方式有四种机制,即随机机制、有序机制、强制有序机制和乒乓机制,迄今为止这一动力学方法仅对随机机制的肌酸激酶进行了实验研究.而其它机制的实验研究尚未见诸报道.我们选用了有序机制的乳酸脱氢酶(LDH),用邻苯二甲醛(OPTA)为抑制剂对该酶的抑制过程进行了实验研究.结果表明,OPTA对该酶的抑制为不可逆抑制.其产物生成与时间的关系曲线符合邹氏方程:[P]=[P]_x(1-e~(-A[OPTA]).由ln([P]_x-[P])对t作图为一直线,表明它的抑制作用为单相动力学过程,抑制剂与酶的结合为一步反应.由直线的斜率A[OPTA]对[OPTA]作图为一过原点的直线.说明表观速度常数A与OPTA的浓度无关.OPTA与酶的结合为非络合型.测得的OPTA与EE-NADH结合的微观速度常数分别为:K(?)=49.6(mmol L)~(-1)min,(?)=2.31(mmol L)min~(-1)(?).明显小于(?)的事实表明.NADH对失活有明显的保护作用.OPTA是一个竞争性的不可逆抑制剂.用传统的方法测得的(?)为42.5(mmol L)min~(-1).与邹氏方法测得的结果非常接近.     

Kinetics of protein modification reactions: analysis of modification-induced protein unfolding

A mathematical treatment of a two-sited, modification-induced protein unfolding model is presented, and it is shown that the dependence of the concentration of modified protein groups on reaction time is described by a linear, second-order, differential equation with nonzero right hand side. The analytic solution of this equation consists of a summation of exponential functions of reaction time. By assigning arbitrary values to the modification and isomerization rate constants of these equations, simulated cases of protein modification are presented, and the apparent end-point of the reaction is determined graphically. It is found that the apparent end-point of the reaction is, in most cases studied, different from the true value of two groups modified per protein molecule, and is a function of both the modification, and isomerization rate constants of the model. The first derivative of the protein modification reaction, at the start of the reaction, [E]'mod (0), is determined, for the same simulated cases of protein modification, by two different analytical methods. It is found that the [E]'mod(0) value, obtained from graphical and numerical analysis data, is in most cases in good agreement with the value expected from first principles. Finally, the different irreversible enzyme inhibition forms, contingent upon the different kinds of the enzyme inactivation-protein modification relationships of the protein modification model under consideration, are presented and discussed.     

Mechanism of action of cAMP-dependent protein kinase. III. Probable role of an enzyme carboxyl group

By the method of chemical modification the active site of cAMP-dependent pig brain protein kinase was shown to contain a carboxyl group. The kinetic parameters of irreversible inhibition of the enzyme by water-soluble carbodiimide in the presence of ethyl ester of glycine were determined. The ionized carboxyl group-containing amino acid residue found is evidently localized in the immediate proximity to the reaction center. The comparison of the reaction rates of phosphate transfer from the intermediate phosphoform of the enzyme under native and denatured conditions suggests that this residue acts as the general base catalyst of this process.     

Modification of maize phosphoenolpyruvate carboxylase by Woodward's reagentK

Maize leaf phosphoenolpyruvate carboxylase was completely and irreversibly inactivated by treatment with micromolar concentrations of Woodward's reagentK (WRK) for about 1 min. The inactivation followed pseudo-first-order reaction kinetics. The order of reaction with respect to WRK showed that the reagent causes formation of reversible enzyme inhibitor complex before resulting in irreversible inactivation. The loss of activity was correlated to the modification of a single carboxyl group per subunit, even though the reagent reacted with 2 carboxyl groups per protomer. Substrate PEP and PEP + Mg²⁺ offered substantial protection against inactivation by WRK. The modified enzyme showed a characteristic absorbance at 346 nm due to carboxyl group modification. The modified enzyme exhibited altered surface charge as seen from the elution profile on FPLC Mono Q anion exchange column. The modified enzyme was desensitized to positive and negative effectors like glucose-6-phosphate and malate. Pretreatment of PEP carboxylase with diethylpyrocarbonate prevented WRK incorporation into the enzyme, suggesting that both histidine and carboxyl groups may be closely physically related. The carboxyl groups might be involved in metal binding during catalysis by the enzyme.     

Modification of maize phosphoenolpyruvate carboxylase by Woodward's reagentK

Maize leaf phosphoenolpyruvate carboxylase was completely and irreversibly inactivated by treatment with micromolar concentrations of Woodward's reagentK (WRK) for about 1 min. The inactivation followed pseudo-first-order reaction kinetics. The order of reaction with respect to WRK showed that the reagent causes formation of reversible enzyme inhibitor complex before resulting in irreversible inactivation. The loss of activity was correlated to the modification of a single carboxyl group per subunit, even though the reagent reacted with 2 carboxyl groups per protomer. Substrate PEP and PEP + Mg²⁺ offered substantial protection against inactivation by WRK. The modified enzyme showed a characteristic absorbance at 346 nm due to carboxyl group modification. The modified enzyme exhibited altered surface charge as seen from the elution profile on FPLC Mono Q anion exchange column. The modified enzyme was desensitized to positive and negative effectors like glucose-6-phosphate and malate. Pretreatment of PEP carboxylase with diethylpyrocarbonate prevented WRK incorporation into the enzyme, suggesting that both histidine and carboxyl groups may be closely physically related. The carboxyl groups might be involved in metal binding during catalysis by the enzyme.     

Modification of Escherichia coli RNA polymerase by diethylpyrocarbonate. II. Binding and unwinding of double-stranded DNA

E. coli DNA dependent RNA polymerase was modified by diethylpyrocarbonate. Binding to a double-stranded DNA and unwinding of the DNA at the enzyme binding site by the modified enzyme were examined. It was found that RNA polymerase reversibly lost the ability to unwind DNA helix as well as the RNA synthetic activity when 9 to 11 histidyl residues of the enzyme were modified. In addition ot modification of the most reactive sulfhydryl or amino groups of the enzyme accompanying histidyl residues modification results in irreversible decrease of the salt concentration which is necessary to remove the enzyme from DNA cellulose column. Further modification of the less reactive sulfhydryl or amino groups leads to irreversible loss of the DNA binding ability and to the enzyme structure alteration.     

The chemical modification of papain with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide.

The reaction of the water-soluble carbodimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), with active papain in the presence of the nucleophile ethyl glycinate results in an irreversible inactivation of the enzyme. This inactivation is accompanied by the derivatization of the catalytically essential thiol group of the enzyme (Cys-25) and by the modification of 6 out of 14 of papain's carboxyl groups and up to 9 out of 19 of the enyzme's tyrosyl residues. No apparent irreversible modification of histidine residues is observed. Mercuripapain is also irreversibly inactivated by EDC/ethyl glycinate, again with the concomitant modification of 6 carboxyl groups, up to 10 tyrosyl residues, and no histidine residues; but in this case there is no thiol derivatization. Treatment of either modified native papain or modified mercuripapain with hydroxylamine results in the complete regeneration of free tyrosyl residues but does not restore any activity. The competitive inhibitor benzamidoacetonitrile substantially protects native papain against inactivation and against the derivatization of the essential thiol group as well as 2 of the 6 otherwise accessible carboxyl groups. The inhibitor has no effect upon tyrosyl modification. These findings are discussed in the context of a possible catalytic role for a carboxyl group in the active site of papain.     

Analysis of cyclic enzyme reaction schemes by the graph-theoretic method

The development of the graph-theoretic method is proposed particularly for the analysis of closed cycles of elementary stages in enzyme reaction schemes. Some simplifications of the graph structure may be based on the application of Kirchhoff's laws to enzyme reaction graphs in the steady-state. The importance of the cyclic processes for enzyme regulations and a principle non-equilibrium of this phenomenon are emphasized. As an example of the regulatory role of cycles "the liberation" from substrate inhibition by substrate analogues is considered. The modification of the graph-theoretic method in the pre-steady-state kinetics for arbitrary initial conditions (for pre-mixing procedures) is also discussed. The necessary and sufficient conditions for damped oscillations in the pre-steady state are formulated which are the equality conditions for some of the rate constants along the cycle (both for reversible and irreversible stages).     

Affinity labelling of alcohol dehydrogenases. Chemical modification of the horse liver and the yeast enzymes with alpha-bromo-beta(5-imidazolyl)-propionic acid and 1,3-dibromoacetone.

1. DL-alpha-Bromo-beta(5-imidazolyl)-propionic acid is a potential affinity labelling reagent for metallo-enzymes. It has been used with the alcohol dehydrogenases from liver and yeast. The liver enzyme is chemically modified and inactivated in a Michaelis-Menten-type reaction, where one molecule of the reagent is bound per subunit. The enzyme is protected from the inhibitor in a competitive manner by imidazole, 2,2'-dipyridyl, 1,10-phenanthroline and cyclohexanone, which all combine with the active-site zinc. The protection by chloride, acetate and NADH, which are considered to bind at the general anion binding site, is not strictly competitive. Inactivation has an optimum at pH 8.5. For the liver enzyme, the reagent was found to decrease the initial rate of ethanol oxidation. Prior to the irreversible alkylation of Cys-46, reversible binding is shown to occur at the active-site zinc atom. The yeast enzyme was extremely resistant to the reagent and no specific modification was found. 2. The potential affinity labelling and crosslinking reagent, symmetrical 1,3-dibromoacetone although unstable, has also been used for chemical modification. With the liver enzyme, concentrations below 5 mM gave a reaction of the Michaelis-Menten-type at pH 7.0. Several ligands known to complex with the active-site region protect the enzyme against the reagent. Dibromoacetone gave rapid inactivation of the yeast enzyme. Despite the fact that a pseudo-first-order reaction was observed with respect to enzyme as well as inhibitor, no saturating effect was found. In this work, dibromoacetone reacted like a monofunctional reagent.     

An active-site lysine in avian liver phosphoenolpyruvate carboxykinase

The participation of lysine in the catalysis by avian liver phosphoenolpyruvate carboxykinase was studied by chemical modification and by a characterization of the modified enzyme. The rate of inactivation by 2,4-pentanedione is pseudo-first-order and linearly dependent on reagent concentration with a second-order rate constant of 0.36 +/- 0.025 M-1 min-1. Inactivation by pyridoxal 5'-phosphate of the reversible reaction catalyzed by phosphoenolpyruvate carboxykinase follows bimolecular kinetics with a second-order rate constant of 7700 +/- 860 M-1 min-1. A second-order rate constant of inactivation for the irreversible reaction catalyzed by the enzyme is 1434 +/- 110 M-1 min-1. Treatment of the enzyme with pyridoxal 5'-phosphate gives incorporation of 1 mol of pyridoxal 5'-phosphate per mole of enzyme or one lysine residue modified concomitant with 100% loss in activity. A stoichiometry of 1:1 is observed when either the reversible or the irreversible reactions catalyzed by the enzyme are monitored. A study of kobs vs pH suggests this active-site lysine has a pKa of 8.1 and a pH-independent rate constant of inactivation of 47,700 M-1 min-1. The phosphate-containing substrates IDP, ITP, and phosphoenolpyruvate offer almost complete protection against inactivation by pyridoxal 5'-phosphate. Modified, inactive enzyme exhibits little change in Mn2+ binding as shown by EPR. Proton relaxation rate measurements suggest that pyridoxal 5'-phosphate modification alters binding of the phosphate-containing substrates. 31P NMR relaxation rate measurements show altered binding of the substrates in the ternary enzyme.Mn2+.substrate complex. Circular dichroism studies show little change in secondary structure of pyridoxal 5'-phosphate modified phosphoenolpyruvate carboxykinase. These results indicate that avian liver phosphoenolpyruvate carboxykinase has one reactive lysine at the active site and it is involved in the binding and activation of the phosphate-containing substrates.     

o-Phthalaldehyde as a probe in the active site of phosphoenolpyruvate carboxylase

Modification of phosphoenolpyruvate carboxylase with o-phthalaldehyde (OPA) resulted in rapid and irreversible inactivation exhibiting biphasic reaction kinetics. The kinetic analysis and correlation of spectral changes with activity indicated that inactivation by OPA results from the modification of two lysine and two cysteine residues per subunit of the enzyme. PEP plus Mg2+ offered substantial protection against modification. Some of the effectors also gave appreciable protection against modification indicating that the residues may be located at or close to the active site. Thus, the results indicate formation of two isoindoles showing the proximity of the essential lysine and cysteine residues at the active site.     

A generalized theoretical treatment of the kinetics of an enzyme-catalysed reaction in the presence of an unstable irreversible modifier

A generalized theoretical treatment of the kinetics of an enzyme-catalysed reaction in the presence of an unstable irreversible inhibitor (or activator) is presented. Analytical expressions describing the time-dependence of product formation have been derived in coefficient form amenable to non-linear regression analysis for two operationally distinct types of reaction mechanism dependent on whether the reaction of the unstable modifier (X) with either or both the free enzyme (E) and enzyme-substrate complex (ES) occurs as a simple bimolecular process, or proceeds through the intermediacy of either or both adsorptive enzyme-modifier (EX) and enzyme-modifier-substrate (EXS) complexes in what may be considered as an extension of the Botts-Morales general modifier mechanism for (stable) reversible enzyme inhibitors and activators. Special cases of both models are classified in an analogous way to the traditional naming of reversible enzyme modifications, and guidelines concerning tests of mechanism and determination of kinetic parameters are given. In particular, it has been shown that kinetic constants describing enzyme inactivation by an unstable site-specific inhibitor forming a reversible EX complex prior to covalent modification step may be determined from a single progress curve. Kinetic analysis of the extended Botts-Morales mechanism describing irreversible enzyme inactivation has demonstrated that analytical expressions describing the time-course of product formation may be derived for a stable modifier by retaining the usual steady-state assumptions regarding the fluxes around ES and EXS provided quasi-equilibrium modifier binding to E and ES is assumed, but for unstable modifiers all of the binding steps must be assumed to be at quasi-equilibrium in the steady-state, except under restrictive circumstances.     

Irreversible inhibition of phosphorylase phosphatase by fluorophosphate.

The inactivation of phosphorylase phosphatase by fluorophosphate is described. The inactivation is dependent upon time and concentration of fluorophosphate and cannot be reversed by removal of fluorophosphate from the enzyme. Acid hydrolysis of fluorophosphate destroys the capacity for inhibition. The inactivation exhibits saturation kinetics. A dissociation constant for the enzyme-fluorophosphate complex and a rate constant for the reaction were calculated to be 5.5 × 10^?3 M and 0.22 min^?1, respectively. A competitive inhibitor, phosphate, protects the enzyme against inactivation. The data are consistent with an irreversible covalent modification of the active site of phosphorylase phosphatase by fluorophosphate.     

Irreversible inhibition of pancreatic lipase by bis-p-nitrophenyl methylphosphonate

The reaction of porcine pancreatic lipase with an organophosphorus compound bis-p-nitrophenyl methylphosphonate (BNMP) resulted in the complete and irreversible inhibition of lipase activity on tributyrin emulsion (25 degrees C, pH 7.5, 40 mM Na-veronal-HCl buffer) whereas the activity of the enzyme on p-nitrophenyl acetate solution remained unchanged. The BNMP-modified enzyme did not bind on hydrophobic interfaces (siliconized glass beads). Tyr 49 was presumed to be the modification site, and the conclusion has been made that this residue is implicated in the interface recognition site of pancreatic lipase.     

The reactions of pyridoxal 5′-phosphate with the M4 and H4 isoenzymes of pig lactate dehydrogenase

The H₄ and M₄ isoenzymes of pig lactate dehydrogenase are both inactivated by reaction with pyridoxal 5′-phosphate. In the early stages, inactivation is largely reversible by the addition of lysine in excess, but may be made irreversible by reduction with borohydride. This indicates that modification of lysine residues probably causes the initial inactivation. Both isoenzymes also undergo a slower process of irreversible inactivation which becomes more evident with increasing concentrations of pyridoxal 5′-phosphate and higher temperature. Although coenzymes give only partial protection of enzyme activity, they nevertheless completely prevent irreversible inactivation. Neither pyruvate nor lactate alone gives any protection. With the M₄ isoenzyme, complete protection against inactivation by pyridoxal 5′-phosphate may be achieved in ternary complexes, but no conditions have been found for complete protection of the H₄ isoenzyme. In the course of irreversible inactivation of H₄ lactate dehydrogenase, complete loss of activity can be correlated with the loss of approximately two free thiol groups per subunit. Present findings with regard to the importance of temperature and reagent concentration in determining the outcome of the chemical modification appear to resolve earlier controversy.     

The reaction of aldolase with 2-methylmaleic anhydride

1. The reaction of rabbit muscle aldolase with 2-methylmaleic anhydride is described. All the protein amino groups can be reversibly blocked. 2. As the reaction proceeds, the enzyme activity decreases until, at about 50% citraconylation of amino groups, the enzyme is completely inhibited. At this stage, little or no dissociation of the enzyme tetramer is observed and 75% of the activity is recoverable on unblocking the amino groups. 3. At 80% blocking, the enzyme is completely dissociated but little enzymic activity is recoverable after unblocking. Inability to recover activity after citraconylation and unblocking correlates with the onset of dissociation of the citraconyl-aldolase seen on ultracentrifugation. 4. The only irreversible modification of the enzyme primary structure detectable after the citraconylation and unblocking reactions is the partial loss of thiol groups. It is probable that this is responsible for the inability to reform active enzyme from the citraconylated subunit. 5. Other reversible side reactions of maleic anhydride and citraconic anhydride that may occur with proteins are discussed.     

DTNB对人肌肌酸激酶不可逆抑制作用的研究

本文研究了DTNB对人肌肌酸激酶的不可逆抑制作用.研究结果表明,与兔肌肌酸激酶不同,人肌肌酸激酶分子中有四个可反应SH.用邹承鲁作图法定量处理结果表明,在这四个可反应的SH中,有一个快反应SH,两个慢反应SH且这两个慢反应SH是酶的必需基团,此外还有一个反应很慢的SH.用邹承鲁提出的在抑制剂存在条件下,酶活性不可逆改变动力学方法,测定了一系列动力学常数,并对DTNB的作用机制进行了探讨.     

A kinetic approach for the study of protein phosphatase-catalyzed regulation of protein kinase activity

The activities of many protein kinases are regulated by phosphorylation. The phosphorylated protein kinases thus represent an important class of substrates for protein phosphatases. However, our ability to study the phosphatase-catalyzed substrate dephosphorylation has been limited in many cases by the difficulty in preparing sufficient amount of stoichiometrically phosphorylated kinases. We have applied the kinetic theory of substrate reaction during irreversible modification of enzyme activity to the study of phosphatase-catalyzed regulation of kinase activity. As an example, we measured the effect of the hematopoietic protein-tyrosine phosphatase (HePTP) on the reaction catalyzed by the fully activated, bisphosphorylated extracellular signal-regulated protein kinase 2 (ERK2/pTpY). Because only a catalytic amount of ERK2/pTpY is required, this method alleviates the need for large quantities of phospho-ERK2. Kinetic analysis of the ERK2/pTpY-catalyzed substrate reaction in the presence of HePTP leads to the determination of the rate constants for the HePTP-catalyzed dephosphorylation of free ERK2/pTpY and ERK2/pTpY*substrate(s) complexes. The data indicate that ERK2/pTpY is a highly efficient substrate for HePTP (k(cat)/K(m) = 3.05 x 10(6) M(-1) s(-1)). The data also show that binding of ATP to ERK2/pTpY has no effect on ERK2/pTpY dephosphorylation by HePTP. In contrast, binding of an Elk-1 peptide substrate to ERK2/pTpY completely blocks the HePTP action. This result indicates that phosphorylation of Tyr185 is important for ERK2 substrate recognition and that binding of the Elk-1 peptide substrate to ERK2/pTpY blocks the accessibility of pTyr185 to HePTP for dephosphorylation. Collectively, the results establish that the kinetic theory of irreversible enzyme modification can be applied to study the phosphatase catalyzed regulation of kinase activity.     

Kinetics of thermal inactivation of penaeus penicillatus acid phosphatase

The kinetics of thermal inactivation of Penaeus penicillatus acid phosphatase have been studied using a kinetic method related to the substrate reaction during irreversible inhibition of the enzyme activity as previously described by Tsou (Adv. Enzymol. Relat. Areas Mol. Biol. (1988) 61, 381-436). The kinetics of thermal inactivation of the enzyme show that the reaction is irreversible. The microscopic rate constants were determined for thermal inactivation of free enzyme and the enzyme--substrate complex. The results show that the presence of substrate has a significant protective effect against thermal inactivation of the enzyme.     

Reinvestigation of the phenacyl bromide modification of alpha-chymotrypsin.

The modification of alpha-chymotrysin with phenacyl bromide has been reinvestigated over a wide pH range. Evidence is presented that indicates that the nature of the phenacyl-modified enzymes prepared by this reaction is dependent upon the pH of the reaction medium. The phenacyl alpha-chymotrypsin produced at low pH is most probably the Met-192 phenacylsulfonium salt, as proposed earlier, since it readily undergoes dealkylation using 2-mercaptoethanol. However, the phenacyl-enzyme prepared at neutral pH possesses a much reduced enzymatic activity and does not react with 2-mercaptoethanol to regenerate native alpha-chymotrypsin. In addition, incubation of the Met-192 phenacyl sulfonium enzyme at neutral pH causes a smooth irreversible change to the new phenacyl-enzyme as monitored by changes in enzymatic activity, susceptibility to dealkylation using 2-mercaptoethanol, and ultraviolet difference absorption spectral properties. The stoichiometries of both the low and neutral pH modification reactions have been determined, using [carbonyl-14C]phyenacyl bromide, to be 1 phenacyl group/enzyme molecule. In efforts to obtain information about the nature and mechanism of formation of the phenacyl alpha-chymotrypsin produced at neutral pH, alkylation reactions of modified alpha-chymotrypsins produced by His-57 functionalization with tosylphenylalanine chloromethyl ketone and by Met-192 oxidation to the sulfoxide have been investigated. The combined results of these studies have been initially interpreted in terms of a neutral pH, phenacyl bromide modification resulting in formation of a new modified enzyme via the Met-192 sulfonium salt.