A substrate-induced change in the stereospecificity of the serine-hydroxymethyltransferase-catalysed exchange of the alpha-protons of amino acids--evidence for a second catalytic site

Labeling of membrane proteins by cell-free expression

The particular advantage of the cell-free reaction is that it allows a plethora of supplementation during protein expression and offers complete control over the available amino acid pool in view of concentration and composition. In combination with the fast and reliable production efficiencies of cell-free systems, the labeling and subsequent structural evaluation of very challenging targets, such as membrane proteins, comes into focus. We describe current methods for the isotopic labeling of cell-free synthesized membrane proteins and we review techniques available to the practitioner pursuing structural studies by nuclear magnetic resonance spectroscopy. Though isotopic labeling of individual amino acid types appears to be relatively straightforward, an ongoing critical issue in most labeling schemes for structural approaches is the selective substitution of deuterons for protons. While few options are available, the continuous refinement of labeling schemes in combination with improved pulse sequences and optimized instrumentation gives promising perspectives for extended applications in the structural evaluation of cell-free synthesized membrane.

Backbone NMR Assignments and H/D Exchange Studies on the Ferric Azide- and Cyanide-Inhibited Forms of Pseudomonas aeruginosa Heme Oxygenase,

The 198 amino acid long heme oxygenase from Pseudomonas aeruginosa (pa-HO) was studied by multinuclear and multidimensional NMR spectroscopy in its paramagnetic cyanide-inhibited (pa-HO-CN) and azide-inhibited (pa-HO-N3) forms. Nearly complete backbone assignments (>93%) of all non-proline residues have been obtained, with the majority of the nonassigned residues corresponding to the first 10 amino terminal residues. Resonances strongly affected by heme iron paramagnetism were assigned with the aid of selective amino acid labeling and experiments tailored to detect fast relaxing signals, whereas the rest of the polypeptide was assigned using conventional three-dimensional NMR experiments. Amide chemical shift assignments were used to monitor the rate of exchange of backbone protons in hydrogen-deuterium exchange experiments. The polypeptide in the pa-HO-N3 complex was found to be significantly less prone to exchange than the polypeptide in pa-HO-CN, which we interpret to indicate that pa-HO-N3 is conformationally less flexible than pa-HO-CN. The differences in protection factors extend to regions of the protein remote from the heme iron and distal ligand. Mapping the differences in protection factors into the X-ray crystal structure of pa-HO [Friedman, J., Lad, L., Li, H., Wilks, A. Poulos, T. L. (2004) Biochemistry 43, 5239-5345] suggests that the distinct chemical properties imparted by the coordination of azide or cyanide to the heme iron [Zeng, Y. Caignan, G. A., Bunce, R. A., Rodríguez, J. C., Wilks, A., Rivera, M. (2005) J. Am. Chem. Soc. 127, 9794-9807] are transmitted to the polypeptide by a network of structural water molecules extending from the active site to the surface of the enzyme. Finally, while the 1H amide resonance of Gly125 was too broad to detect, the corresponding 15N resonance exhibits a large downfield shift, large line width, steep temperature dependence, and a larger than usual upfield deuterium isotope effect. These properties indicate unpaired spin delocalization from the heme iron into the Gly 15N atom via formation of a hydrogen bond between the coordinated azide nitrogen and the Gly125 N-H.

The stereospecificity and catalytic efficiency of the tryptophan synthase-catalysed exchange of the alpha-protons of amino acids

13C-NMR has been used to follow the tryptophan synthase (EC 4.2.1.20) catalysed hydrogen-deuterium exchange of the pro-2R and pro-2S protons of [2-13C]glycine at pH 7.8. 1H-NMR has also been used to follow the tryptophan-synthase-catalysed hydrogen-deuterium exchange of the alpha-protons of a range of L- and D-amino acids at pH 7.8. The pK(a) values of the alpha-protons of these amino acids have been estimated and we have determined whether or not their exchange rates can be predicted from their pK(a) values. With the exception of tryptophan and norleucine, the stereospecificities of the first-order alpha-proton exchange rates are independent of the size and electronegativity of the amino acid R-group. Similar results are obtained with the second-order alpha-proton exchange rates, except that both L-tryptophan and L-serine have much higher stereospecificities than all the other amino acids studied.

Threonine aldolase and alanine racemase: novel examples of convergent evolution in the superfamily of vitamin B6-dependent enzymes

Vitamin B(6)-dependent enzymes may be grouped into five evolutionarily unrelated families, each having a different fold. Within fold type I enzymes, L-threonine aldolase (L-TA) and fungal alanine racemase (AlaRac) belong to a subgroup of structurally and mechanistically closely related proteins, which specialised during evolution to perform different functions. In a previous study, a comparison of the catalytic properties and active site structures of these enzymes suggested that they have a catalytic apparatus with the same basic features. Recently, recombinant D-threonine aldolases (D-TAs) from two bacterial organisms have been characterised, their predicted amino acid sequences showing no significant similarities to any of the known B(6) enzymes. In the present work, a comparative structural analysis suggests that D-TA has an alpha/beta barrel fold and therefore is a fold type III B(6) enzyme, as eukaryotic ornithine decarboxylase (ODC) and bacterial AlaRac. The presence of both TA and AlaRac in two distinct evolutionary unrelated families represents a novel and interesting example of convergent evolution. The independent emergence of the same catalytic properties in families characterised by completely different folds may have not been determined by chance, but by the similar structural features required to catalyse pyridoxal phosphate-dependent aldolase and racemase reactions.

Stereospecificity of alpha-proton exchange reactions catalysed by pyridoxal-5'-phosphate-dependent enzymes

A NMR method for quantifying the catalytic efficiency and stereospecificity of the exchange of the alpha-protons of glycine is described. It is used to determine how the binding of the alpha-carboxylate group of amino acids contributes to the stereospecificity of exchange reactions catalysed by tryptophan synthase, serine hydroxymethyltransferase and a catalytic antibody utilising pyridoxal-5'-phosphate (PLP) as a cofactor. Using larger substrates, it is shown how the size of the amino acid side chain contributes to the stereospecificity of exchange. Mutants of aspartate aminotransferase are used to determine how substrate binding controls the catalytic efficiency and stereospecificity of the exchange of the alpha-protons of aspartate and glutamate. Evidence is presented which shows that with serine hydroxymethyltransferase, L-norleucine is not bound at the same catalytic site as glycine. Finally the catalytic efficiency and stereospecificity of the alpha-proton exchange reactions catalysed by all the PLP-dependent catalysts examined are compared.

X-ray Structures of Threonine Aldolase Complexes: Structural Basis of Substrate Recognition†,‡

L-Threonine acetaldehyde-lyase (threonine aldolase, TA) is a pyridoxal-5'-phosphate-dependent (PLP) enzyme that catalyzes conversion of L-threonine or L-allo-threonine to glycine and acetaldehyde in a secondary glycine biosynthetic pathway. X-ray structures of Thermatoga maritima TA have been determined as the apo-enzyme at 1.8 A resolution and bound to substrate L-allo-threonine and product glycine at 1.9 and 2.0 A resolution, respectively. Despite low pairwise sequence identities, TA is a member of aspartate aminotransferase (AATase) fold family of PLP enzymes. The enzyme forms a 222 homotetramer with the PLP cofactor bound via a Schiff-base linkage to Lys199 within a domain interface. The structure reveals bound calcium and chloride ions that appear to contribute to catalysis and oligomerization, respectively. Although L-threonine and L-allo-threonine are substrates for T. maritima TA, enzymatic assays revealed a strong preference for L-allo-threonine. Structures of the external aldimines with substrate/product reveal a pair of histidines that may provide flexibility in substrate recognition. Variation in the threonine binding pocket may explain preferences for L-allo-threonine versus L-threonine among TA family members.

l-Threonine aldolase, serine hydroxymethyltransferase and fungal alanine racemase. A subgroup of strictly related enzymes specialized for different functions

Serine hydroxymethyltransferase (SHMT) is a member of the fold type I family of vitamin B6-dependent enzymes, a group of evolutionarily related proteins that share the same overall fold. The reaction catalysed by SHMT, the transfer of Cbeta of serine to tetrahydropteroylglutamate (H4PteGlu), represents in the cell an important link between the breakdown of amino acids and the metabolism of folates. In the absence of H4PteGlu and when presented with appropriate substrate analogues, SHMT shows a broad range of reaction specificity, being able to catalyse at appreciable rates retroaldol cleavage, racemase, aminotransferase and decarboxylase reactions. This apparent lack of specificity is probably a consequence of the particular catalytic apparatus evolved by SHMT. An interesting question is whether other fold type I members that normally catalyse the reactions which for SHMT could be considered as 'forced errors', may be close relatives of this enzyme and have a catalytic apparatus with the same basic features. As shown in this study, l-threonine aldolase from Escherichia coli is able to catalyse the same range of reactions catalysed by SHMT, with the exception of the serine hydroxymethyltransferase reaction. This observation strongly suggests that SHMT and l-threonine aldolase are closely related enzymes specialized for different functions. An evolutionary analysis of the fold type I enzymes revealed that SHMT and l-threonine aldolase may actually belong to a subgroup of closely related proteins; fungal alanine racemase, an extremely close relative of l-threonine aldolase, also appears to be a member of the same subgroup. The construction of three-dimensional homology models of l-threonine aldolase from E. coli and alanine racemase from Cochliobolus carbonum, and their comparison with the SHMT crystal structure, indicated how the tetrahydrofolate binding site might have evolved and offered a starting point for further investigations.

The aspartate aminotransferase-catalysed exchange of the alpha-protons of aspartate and glutamate: the effects of the R386A and R292V mutations on this exchange reaction

1H-NMR was used to follow the aspartate aminotransferase-catalysed exchange of the alpha-protons of aspartate and glutamate. The effect of the concentrations of both the amino acids and the cognate keto acids on exchange rates was determined for wild-type and the R386A and R292V mutant forms of aspartate aminotransferase. The wild-type enzyme is found to be highly stereospecific for the exchange of the alpha-protons of L-aspartate and L-glutamate. The R386A mutation which removes the interaction of Arg-386 with the alpha-carboxylate group of aspartate causes an approximately 10,000-fold decrease in the first order exchange rate of the alpha-proton of L-aspartate. The R292V mutation which removes the interaction of Arg-292 with the beta-carboxylate group of L-aspartate and the gamma-carboxylate group of L-glutamate causes even larger decreases of 25,000- and 100,000-fold in the first order exchange rate of the alpha-proton of L-aspartate and L-glutamate respectively. Apparently both Arg-386 and Arg-292 must be present for optimal catalysis of the exchange of the alpha-protons of L-aspartate and L-glutamate, perhaps because the interaction of both these residues with the substrate is essential for inducing the closed conformation of the active site.

The effect of histidine-228 on the catalytic efficiency and stereospecificity of the serine hydroxymethyltransferase catalysed exchange of the alpha-protons of amino acids

13C-NMR has been used to determine how replacing the histidine-228 residue of serine hydroxymethyltransferase (EC 2.1.2.1) by an asparagine residue effects the catalysis of the hydrogen-deuterium exchange of the alpha-protons of [2-13C]glycine at pH 7.8. The H228N mutation did not lead to a large change in the stereospecificity of the first order exchange rates of the alpha-protons of glycine both in the presence and in the absence of tetrahydrofolate. However, the mutation did lead to large decreases in the stereospecificity of the second order exchange rate in both the presence and the absence of tetrahydrofolate. In the absence of tetrahydrofolate this decrease in stereospecificity was largely due to the decrease in the second order exchange rate of the pro-2S proton, while in the presence of tetrahydrofolate the large increase in the second order exchange rate of the pro-2R proton of glycine made a major contribution. We conclude that the H228N mutation has significant effects on the catalytic efficiency and stereospecificity of the second order exchange reactions, but only a small effect on the corresponding first order exchange reactions.

The pyridoxal-5'-phosphate-dependent catalytic antibody 15A9: its efficiency and stereospecificity in catalysing the exchange of the alpha-protons of glycine

13C-NMR has been used to follow the exchange of the alpha-protons of [2-(13)C]glycine in the presence of pyridoxal-5'-phosphate and the catalytic antibody 15A9. In the presence of antibody 15A9 the 1st order exchange rates for the rapidly exchanged proton of [2-(13)C]glycine were only 25 and 150 times slower than those observed with tryptophan synthase (EC 4.2.1.20) and serine hydroxymethyltransferase (EC 2.1.2.1). The catalytic antibody increases the 1st order exchange rates of the alpha-protons of [2-(13)C]glycine by at least three orders of magnitude. We propose that this increase is largely due to an entropic mechanism which results from binding the glycine-pyridoxal-5'-phosphate Schiff base. The 1st and 2nd order exchange rates of the pro-2S proton have been determined but we were only able to determine the 2nd order exchange rate for the pro-2R proton of glycine. In the presence of 50 mM glycine the antibody preferentially catalyses the exchange of the pro-2S proton of glycine. The stereospecificity of the 2nd order exchange reaction was quantified and we discuss mechanisms which could account for the observed stereospecificity.