Detection of explosive remnants of war by neutron thermalisation.

The HYDAD-D landmine detector (Brooks and Drosg, 2005) has been modified and field-tested for 17 months in a variety of soil conditions. Test objects containing about the same mass of hydrogen (20g) as small explosive remnants of war, such as antipersonnel landmines, were detected with efficiency 100% when buried at cover depths up to 10cm. The false alarm rate under the same conditions was 9%. Plots of detection efficiency versus false alarm rate are presented.

Activation of thiamin diphosphate in enzymes.

Activation of the coenzyme ThDP was studied by measuring the kinetics of deprotonation at the C2 carbon of thiamin diphosphate in the enzymes pyruvate decarboxylase, transketolase, pyruvate dehydrogenase complex, pyruvate oxidase, in site-specific mutant enzymes and in enzyme complexes containing coenzyme analogues by proton/deuterium exchange detected by 1H-NMR spectroscopy. The respective deprotonation rate constant is above the catalytic constant in all enzymes investigated. The fast deprotonation requires the presence of an activator in pyruvate decarboxylase from yeast, showing the allosteric regulation of this enzyme to be accomplished by an increase in the C2-H dissociation rate of the enzyme-bound thiamin diphosphate. The data of the thiamin diphosphate analogues and of the mutant enzymes show the N1' atom and the 4'-NH2 group to be essential for the activation of the coenzyme and a conserved glutamate involved in the proton abstraction mechanism of the enzyme-bound thiamin diphosphate.

Examination of the thiamin diphosphate binding site in yeast transketolase by site-directed mutagenesis.

The role of two conserved amino acid residues in the thiamin diphosphate binding site of yeast transketolase has been analyzed by site-directed mutagenesis. Replacement of E162, which is part of a cluster of glutamic acid residues at the subunit interface, by alanine or glutamine results in mutant enzymes with most catalytic properties similar to wild-type enzyme. The two mutant enzymes show, however, significant increases in the K0.5 values for thiamin diphosphate in the absence of substrate and in the lag of the reaction progress curves. This suggests that the interaction of E162 with residue E418, and possibly E167, from the second subunit is important for formation and stabilization of the transketolase dimer. Replacement of the conserved residue D382, which is buried upon binding of thiamin diphosphate, by asparagine and alanine, results in mutant enzymes severely impaired in thiamin diphosphate binding and catalytic efficiency. The 25-80-fold increase in K0.5 for thiamin diphosphate suggests that D382 is involved in cofactor binding, probably by electrostatic compensation of the positive charge of the thiazolium ring and stabilization of a flexible loop at the active site. The decrease in catalytic activities in the D382 mutants indicates that this residue might also be important in subsequent steps in catalysis.

How thiamine diphosphate is activated in enzymes.

The controversial question of how thiamine diphosphate, the biologically active form of vitamin B1, is activated in different enzymes has been addressed. Activation of the coenzyme was studied by measuring thermodynamics and kinetics of deprotonation at the carbon in the 2-position (C2) of thiamine diphosphate in the enzymes pyruvate decarboxylase and transketolase by use of nuclear magnetic resonance spectroscopy, proton/deuterium exchange, coenzyme analogs, and site-specific mutant enzymes. Interaction of a glutamate with the nitrogen in the 1'-position in the pyrimidine ring activated the 4'-amino group to act as an efficient proton acceptor for the C2 proton. The protein component accelerated the deprotonation of the C2 atom by several orders of magnitude, beyond the rate of the overall enzyme reaction. Therefore, the earlier proposed concerted mechanism or stabilization of a C2 carbanion can be excluded.

Identification of catalytically important residues in yeast transketolase.

The possible roles of four histidine residues in the active site of yeast transketolase were examined by site-directed mutagenesis. Replacement of the invariant His69 with alanine yielded a mutant enzyme with 1.5% of the specific activity of the wild-type enzyme and with an increased KM for the donor. This residue is located at the bottom of the substrate cleft close to the C1 hydroxyl group of the donor substrate, and the side chain of His69 might be required for recognition of this hydroxyl group and possibly for maintenance of the proper orientation of the reaction intermediate, (alpha, beta-dihydroxyethyl)thiamin diphosphate. Amino acid replacements of His481 by alanine, serine, and glutamine resulted in mutant enzymes with significantly increased KM values for the donor substrate and specific activities of 4.4%, 1.9%, and 5.5% of the wild-type enzyme. The kinetic data suggest that this residue, although close to the C2 carbonyl oxygen of the substrate, is not absolutely required for stabilization of the negative charge that develops at this oxygen in the transition state. This points toward the 4'-NH2 group of the pyrimidine ring of thiamin diphosphate as the major source of charge stabilization. Mutations at positions His30 and His263 result in mutant enzymes severely impaired in catalytic activity (1.5% and less of the activity of wild-type transketolase). The KM value for the donor substrate was increased for the His30Ala mutant but remained unchanged in the His263Ala enzyme. The side chains of both residues interact with the C3 hydroxyl group of the donor substrate, and the results indicate that the two residues act in concert during proton abstraction of the C3 hydroxyl proton during catalysis.

His103 in yeast transketolase is required for substrate recognition and catalysis.

Crystallographic studies of thiamin-diphosphate-dependent transketolase from Saccharomyces cerevisiae suggested the invariant active-site residue H103 as a possible enzymic group binding the C1 hydroxyl group of the donor substrate and stabilizing the reaction intermediate. To test this hypothesis, H103 was replaced by alanine, asparagine and phenylalanine using site-directed mutagenesis. The crystallographic analysis of the mutant transketolases verified that no structural changes occurred as a consequence of the side-chain replacements. The residual catalytic activities of the mutant enzymes were 4.3% for the H103A, 2.4% for the H103N and 0.1% for the H103F mutant transketolase. Further kinetic analysis of the H103A and H103N mutant enzymes showed that the Km values for the coenzyme were increased by about eightfold. The Km values for the acceptor substrate ribose 5-phosphate were similar to the Km value for wild-type transketolase. However, the Km value for the donor substrate, xylulose 5-phosphate is increased more than tenfold in these two mutants. Circular dichroism spectra of the mutant enzymes also indicated a weaker binding of the donor substrate and/or a less stable reaction intermediate. These observations provide further evidence in support of the proposed role for this invariant residue in recognition of the donor substrate by forming a hydrogen bond between the side chain of H103 and the C1 hydroxyl group of the sugar phosphate. The significant decrease in catalytic activity suggests that this residue also facilitates catalysis, possibly by maintaining the optimal orientation of the donor substrate and reaction intermediates.

Analysis of an invariant cofactor-protein interaction in thiamin diphosphate-dependent enzymes by site-directed mutagenesis. Glutamic acid 418 in transketolase is essential for catalysis.

A homologous expression system and a purification protocol for pure, highly active recombinant yeast transketolase have been developed. The invariant transketolase residue Glu418, which forms a hydrogen bond to the N-1' nitrogen atom of the pyrimidine ring of the cofactor thiamin diphosphate has been replaced by glutamine and alanine. Crystallographic analyses of the mutants show that these amino acid substitutions do not induce structural changes beyond the site of mutation. In both cases, the cofactor binds in a manner identical to the wild-type enzyme. Significant differences in the CD spectra of the mutant transketolases compared with the spectrum of wild-type enzyme indicate differences in the electron distribution of the aminopyrimidine ring of the cofactor. The E418Q mutant shows 2% and the E418A mutant shows about 0.1% of the catalytic activity of wild-type enzyme. The affinities of the mutant enzymes for thiamin diphosphate are comparable with wild-type transketolase. The hydrogen bond between the coenzyme and the side chain of Glu418 is thus not required for coenzyme binding but essential for catalytic activity. The results demonstrate the functional importance of this interaction and support the molecular model for cofactor deprotonation, the first step in enzymatic thiamin catalysis.