Computer modeling of transketolase-like protein, TKTL1, a marker of certain tumor tissues.

A computer model of the spatial structure of transketolase-like protein (TKTL1), a marker of certain tumor tissues, has been constructed using the known spatial structure of transketolase found in normal human tissues. The structure of the two proteins at all levels of their organization has also been compared. On the basis of the revealed differences in structures of these proteins, we assume it is unlikely that TKTL1 can be a thiamine diphosphate-dependent protein capable of catalyzing the transketolase reaction.

Interaction of transketolase from human tissues with substrates.

The Michaelis constant values for substrates of transketolase from human tissues were determined over a wide range of substrate concentrations. It is shown that K(m) values determined by other authors are significantly overestimated and explained why this is so.

Isolation and properties of human transketolase.

Recombinant human (His)(6)-transketolase (hTK) was obtained in preparative amounts by heterologous expression of the gene encoding human transketolase in Escherichia coli cells. The enzyme, isolated in the form of a holoenzyme, was homogeneous by SDS-PAGE; a method for obtaining the apoenzyme was also developed. The amount of active transketolase in the isolated protein preparation was correlated with the content of thiamine diphosphate (ThDP) determined in the same preparation. Induced optical activity, facilitating studies of ThDP binding by the apoenzyme and measurement of the transketolase reaction at each stage, was detected by circular dichroism spectroscopy. A single-substrate reaction was characterized, catalyzed by hTK in the presence of the donor substrate and in the absence of the acceptor substrate. The values of the Michaelis constant were determined for ThDP and a pair of physiological substrates of the enzyme (xylulose 5-phosphate and ribose 5-phosphate).

Halogenated pyruvate derivatives as substrates of transketolase from Saccharomyces cerevisiae.

Pyruvate derivatives halogenated at C3 were shown to be donor substrates in the transketolase reaction. No drastic differences between the derivatives were observed in the value of the catalytic constant, whereas the Michaelis constant increased in the following order: Br-pyruvate < Cl-pyruvate < Cl2-pyruvate < F-pyruvate < Br2-pyruvate. The presence of the halogenated pyruvate derivatives increased the affinity of apotransketolase for the coenzyme; of note, the extent of this effect was equal with both of the active centers of the enzyme. In contrast, the presence of any other substrate known to date, including hydroxypyruvate (i.e. pyruvate hydroxylated at C3), induced nonequivalence of the active centers in that they differed in the extent to which the affinity for the coenzyme increased. Consequently, the beta-hydroxyl of dihydroxyethylthiamine diphosphate (an intermediate of the transketolase reaction) played an important role in the phenomenon of nonequivalence of the active centers associated with the coenzyme binding. The fundamental possibility was demonstrated of using halogenated pyruvate derivatives as donors of the halogen-hydroxyethyl group in organic synthesis of halogenated carbohydrates involving transketolase.

New function of the amino group of thiamine diphosphate in thiamine catalysis.

In this work, we investigated the rate of formation of the central intermediate of the transketolase reaction with thiamine diphosphate (ThDP) or 4'-methylamino-ThDP as cofactors and its stability using stopped-flow spectroscopy and circular dichroism (CD) spectroscopy. The intermediates of the transketolase reaction were analyzed by NMR spectroscopy. The kinetic stability of the intermediate was shown to be dependent on the state of the amino group of the coenzyme. The rates of the intermediate formation were the same in the case of the native and methylated ThDP, but the rates of the protonation or oxidation of the complex in the ferricyanide reaction were significantly higher in the complex with methylated ThDP. A new negative band was detected in the CD spectrum of the complex transketolase--4'-methylamino-ThDP corresponding to the protonated dihydroxyethyl-4'-methylamino-ThDP released from the active sites of the enzyme. These data suggest that transketolase in the complex with the NH2-methylated ThDP exhibits dihydroxyethyl-4'-methylamino-ThDP-synthase activity. Thus, the 4'-amino group of the coenzyme provides kinetic stability of the central intermediate of the transketolase reaction, dihydroxyethyl-ThDP.

Which stage of the process of apotransketolase interaction with thiamine diphosphate is affected by the regulatory activity of the donor substrate?

The interaction of thiamine diphosphate (ThDP) with transketolase (TK) involves at least two stages: [formula: see text] During the first stage, an inactive intermediate complex (TK...ThDP) is formed, which is then transformed into a catalytically active holoenzyme (TK* - ThDP). The second stage is related to conformational changes of the protein. In the preceding publication (Esakova, O. A., Meshalkina, L. E., Golbik, R., Hübner, G., and Kochetov, G. A. Eur. J. Biochem. 2004, 271, 4189 - 4194) we reported that the affinity of ThDP for TK considerably increases in the presence of the donor substrate, which may be a mechanism whereby the activity of the enzyme is regulated under the conditions of the coenzyme deficiency. Here, we demonstrate that the substrate affects the stage of the reverse conformational transition, characterized by the constant k(-1): in the presence of the substrate, its value is decreased several fold, whereas K(d) and k(+1) remain unchanged.

Effect of transketolase substrates on holoenzyme reconstitution and stability.

The influence of transketolase substrates on the interaction of apotransketolase with its coenzyme thiamine diphosphate (TDP) and on the stability of the reconstituted holoenzyme was studied. Donor substrates increased the affinity of the coenzyme for transketolase, whereas acceptor substrate did not. In the presence of magnesium ions, the active centers of transketolase initially identical in TDP binding lose their equivalence in the presence of donor substrates. The stability of transketolase depended on the cation type used during its reconstitution--the holoenzyme reconstituted in the presence of calcium ions was more stable than the holoenzyme produced in the presence of magnesium ions. In the presence of donor substrate, the holoenzyme stability increased without depending on the cation used during the reconstitution. Donor substrate did not influence the interaction of apotransketolase with the inactive analog of the coenzyme N3'-pyridyl thiamine diphosphate and did not stabilize the transketolase complex with this analog. The findings suggest that the effect of the substrate on the interaction of the coenzyme with apotransketolase and on stability of the reconstituted holoenzyme is caused by generation of 2-(alpha,beta-dihydroxyethyl)thiamine diphosphate (an intermediate product of the transketolase reaction), which has higher affinity for apotransketolase than TDP.

Induced absorption band of holotransketolase and its interpretation.

It has long been known that formation of a catalytically active holotransketolase from the apoenzyme and thiamine diphosphate (ThDP) is accompanied by appearance, in both the absorption and CD spectra, of a new band. Binding and subsequent conversion of transketolase substrates bring about changes in the intensity of this band. The observation of these changes allows the investigator to monitor the coenzyme-to-apoenzyme binding and the conversion of the substrates during the transketolase reaction and thus to kinetically characterize its individual steps. As regards the new absorption band induced by ThDP binding, its nature, until recently, remained unknown. The reason for its appearance was considered to be either the formation of a charge transfer complex between ThDP and tryptophan (phenylalanine) residue or stacking interaction between the residues of aromatic amino acids. They are thought to be brought together as a result of conformational changes of the apoenzyme during its interaction with the coenzyme. However none of these hypotheses had been substantiated experimentally. According to our hypothesis, the induced absorption band is that of the imino form of ThDP resulting from three contributing features of the ThDP binding site of transketolase: the relative hydrophobicity of this site, hydrogen bonding of the N1;-atom of the ThDP aminopyrimidine ring to Glu418, and base stacking interactions between the aminopyrimidine ring of ThDP and Phe445.

Cleaving of ketosubstrates by transketolase and the nature of the products formed.

The interaction of transketolase ketosubstrates with the holoenzyme has been studied. On addition of ketosubstrates cleaving both irreversibly (hydroxypyruvate) and reversibly (xylulose 5-phosphate), identical changes in the CD spectrum at 300-360 nm are observed. The changes in this spectral region, as previously shown, are due to the formation of the catalytically active holoenzyme from the apoenzyme and the coenzyme, and the cleavage of ketosubstrates by transketolase. The identity of the changes in transketolase CD spectrum caused by the addition of reversibly or irreversibly cleaving substrates indicates that in the both cases the changes are due to the formation of an intermediate product of the transketolase reaction--a glycolaldehyde residue covalently bound to the coenzyme within the holoenzyme molecule. Usually, in the course of the transferase reaction, the glycolaldehyde residue is transferred to an aldose (acceptor substrate), resulting in the recycling of the holoenzyme free of the glycolaldehyde residue. The removal of the glycolaldehyde residue from the holoenzyme appears to proceed even in the absence of an aldose. However, the glycolaldehyde cannot be found the free state because it condenses with another glycolaldehyde residue formed in the course of the cleavage of another ketosubstrate molecule yielding erythrulose.

One-substrate transketolase-catalyzed reaction.

Apart from catalyzing the common two-substrate reaction with ketose as donor substrate and aldose as acceptor substrate, transketolase is also able to catalyze a one-substrate reaction utilizing only ketose (xylulose 5-phosphate) as substrate. The products of this one-substrate reaction were glyceraldehyde 3-phosphate and erythrulose. No free glycolaldehyde (a product of xylulose 5-phosphate splitting in the transketolase reaction) was revealed.

Acceptor substrate inhibits transketolase competitively with respect to donor substrate.

Two substrates of the transketolase reaction are known to bind with the enzyme according to a ping-pong mechanism [1]. It is shown in this work that high concentrations of ribose-5-phosphate (acceptor substrate) compete with xylulose-5-phosphate (donor substrate), suppressing the transketolase activity (Ki = 3.8 mM). However, interacting with the donor-substrate binding site on the protein molecule, the acceptor substrate, unlike the donor substrate, does not cause any change in the active site of the enzyme. The data are interesting in terms of studying the regulatory mechanism of the transketolase activity and the structure of the enzyme-substrate complex.

Determination of constants of substrate primary binding with baker's yeast transketolase by kinetic modelling.

A kinetic model of bisubstrate reaction catalyzed by baker's yeast transketolase is proposed. The model considers individual stages of substrates reversible primary binding. The model corresponds to the observed kinetics of product accumulation within a wide range of initial substrate concentrations. Kinetic parameters for the best simulation of the experimental data are defined. The equilibrium constants of the primary binding of both the initial and produced ketose and also the initial aldose were unequivocally determined by varying the initial substrate concentrations. The dissociation constants of the primary enzyme-substrate complex for the initial ketose (xylulose 5-phosphate) and the reaction product (sedoheptulose 7-phosphate) were found to differ by more than by two orders of magnitude. The result is discussed in the context of the hypothesis of flip-flop functioning of the transketolase active sites.

The presence of a hydroxyl group at the C-1 atom of the transketolase substrate molecule is necessary for the enzyme to perform the transferase reaction.

Transketolase catalyzes the transfer of an aldehyde residue from keto sugars to aldo sugars. The intermediate product is dihydroxyethylthiamine pyrophosphate (DHETPP). In the absence of an acceptor substrate, the reaction is stopped at this stage and DHETPP does not undergo subsequent transformations. Pyruvate decarboxylase catalyses pyruvate decarboxylation to yield free aldehyde. The intermediate product is hydroxyethylthiamine pyrophosphate (HETPP). It differs from DHETPP only in that it has no hydroxyl at the C-2 atom of the aldehyde residue. We have shown that transketolase can bind HETPP and split the aldehyde residue from it. This fact suggests that the path of the reaction is determined by the absence (in HETPP) or presence (in DHETPP) of a hydroxyl group. In the former case the reaction will yield free aldehyde, in the latter the aldehyde residue will be transferred onto an acceptor substrate.

A method for determination of transketolase activity based on the use of a pH indicator.

A new method for assaying transketolase activity is proposed. The method consists in recording the pH changes in the course of the enzymatic reaction and is based on the use of the pH-indicator p-nitrophenol. When p-nitrophenol is added to a reaction mixture containing hydroxypyruvate and glycolaldehyde as substrates the absorbance increases. The rate of the change of absorbance is proportional to the enzyme concentration.

[Functional carboxylic group in the active center of transketolase]. / Funktsional'naia karboksil'naia gruppa v aktivnom tsentre transketolazy.

Baker's yeast transketolase is rapidly inactivated in the presence of carboxylic group modifiers, i.e., 1-ethyl-3(3'-dimethylaminopropyl)-carbodiimide or Woodward's reagent K. This inactivation is due to modification of the carboxylic group in the enzyme active center. The essential groups localized in the two active centers of transketolase differ in the rate of modification; accordingly, the inactivation kinetics appears as biphasic. A complete loss of the enzyme activity occurs as a result of modification of one carboxylic group per enzyme active center. The pKa value of modifiable groups is equal to about 6.5. This modification decreases by two orders of magnitude the affinity of the substrate for the active center. The carboxylic groups are not directly involved in the interaction with the substrates; their modification does not significantly affect the coenzyme binding. It is supposed that these groups are responsible for the deprotonation of the second carbon in the thiamine pyrophosphate thiazolium ring.

An investigation of the carboxyl group function in the active center of transketolase.

Transketolase from baker's yeast is rapidly inactivated in the presence of 1-ethyl-3 (3'-dimethylaminopropyl)-carbodiimide. pKa of the modified carboxyl groups is approximately 6.5. An investigation of the initial steps of enzymatic catalysis monitored by a changes in the circular dichroism spectra and in an oxidation reaction with ferricyanide made it possible to conclude that the modification interferes with the donor substrate attachment to the enzyme. Evidence obtained was suggesting that the carboxyl group of the active center facilitates dissociation of a proton from the carbon atom in the second position of the thiamine pyrophosphate thiazolium ring.

The carboxyl group in the active center of transketolase.

Transketolase from baker's yeast is rapidly inactivated in the presence of 1-ethyl-3 (3'-dimethylaminopropyl)-carbodiimide or Woodward's reagent K. In both cases the kinetics of inactivation is biphasic, which agrees with the presence of two active centers in the enzyme molecule differing in their sensitivity to the inhibitors. There is some evidence that inactivation of transketolase is due to modification of carboxyl groups of enzyme. Complete inactivation is achieved by modification of one carboxyl per active site of the enzyme. The experimental results suggest that the carboxyl group is essential for the enzymatic activity of transketolase.

The functional identity of the active centres of transketolase.

Direct determination of the number of catalytically active molecules of the coenzyme in holotransketolase (sedoheptulose-7-phosphate:D-glyceraldehyde-3-phosphate glycoaldehydetransferase, EC 2.2.1.1) has corroborated our previous data indicating that in the native enzyme there are two active centres. They have been provided to be functionally identical. It has been shown that the decrease in the specific activity of transketolase during its storage is due to inactivation of one of the active centres, having a lower affinity for the coenzyme. The second active centre retains thereby its full catalytic activity.