Triosephosphate isomerase: a highly evolved biocatalyst.

Triosephosphate isomerase (TIM) is a perfectly evolved enzyme which very fast interconverts dihydroxyacetone phosphate and D: -glyceraldehyde-3-phosphate. Its catalytic site is at the dimer interface, but the four catalytic residues, Asn11, Lys13, His95 and Glu167, are from the same subunit. Glu167 is the catalytic base. An important feature of the TIM active site is the concerted closure of loop-6 and loop-7 on ligand binding, shielding the catalytic site from bulk solvent. The buried active site stabilises the enediolate intermediate. The catalytic residue Glu167 is at the beginning of loop-6. On closure of loop-6, the Glu167 carboxylate moiety moves approximately 2 Å to the substrate. The dynamic properties of the Glu167 side chain in the enzyme substrate complex are a key feature of the proton shuttling mechanism. Two proton shuttling mechanisms, the classical and the criss-cross mechanism, are responsible for the interconversion of the substrates of this enolising enzyme.

Insights into Src kinase functions: structural comparisons.

Recent structures of Src tyrosine kinases reveal complex mechanisms for regulation of enzymatic activity. The regulatory SH3 and SH2 domains bind to the back of the catalytic kinase domain via a linker region that joins the SH2 domain to the catalytic domain. Members of a subgroup of the Src kinase family show distinct features in this linker and in the loops that interact with it. Hydrophobicity of key residues in this region is important for intramolecular regulation. The kinases Abl, Btk and Csk seem to have the same molecular architecture as Src. Structural comparisons between serine/threonine and tyrosine kinases indicate a specific twisting mechanism involving the N- and C-terminal lobes of the catalytic domain. This motion could provide insights into the various mechanisms used to regulate kinase activity.

The diverse world of coenzyme A binding proteins.

Coenzyme A is involved in a number of important metabolic pathways. Recently the structures of several coenzyme A binding proteins have been determined. We compare in some detail the structures of seven different coenzyme A protein complexes. These seven proteins all have distinctly different folds.

Two crystal structures of N-acetyltransferases reveal a new fold for CoA-dependent enzymes.

Coenzyme A (CoA) is well known for its importance in various metabolic pathways. The recent determination of the structures of several CoA-dependent N-acylating enzymes highlights the importance of the acyl-CoA molecule for intracellular regulation and reveals a novel fold. The N-acetyltransferase fold defines yet another protein superfamily and adds to the already diverse world of CoA-dependent enzymes.

A biosynthetic thiolase in complex with a reaction intermediate: the crystal structure provides new insights into the catalytic mechanism.

BACKGROUND: Thiolases are ubiquitous and form a large family of dimeric or tetrameric enzymes with a conserved, five-layered alphabetaalphabetaalpha catalytic domain. Thiolases can function either degradatively, in the beta-oxidation pathway of fatty acids, or biosynthetically. Biosynthetic thiolases catalyze the biological Claisen condensation of two molecules of acetyl-CoA to form acetoacetyl-CoA. This is one of the fundamental categories of carbon skeletal assembly patterns in biological systems and is the first step in a wide range of biosynthetic pathways, including those that generate cholesterol, steroid hormones, and various energy-storage molecules. RESULTS: The crystal structure of the tetrameric biosynthetic thiolase from Zoogloea ramigera has been determined at 2.0 A resolution. The structure contains a striking and novel 'cage-like' tetramerization motif, which allows for some hinge motion of the two tight dimers with respect to each other. The protein crystals were flash-frozen after a short soak with the enzyme's substrate, acetoacetyl-CoA. A reaction intermediate was thus trapped: the enzyme tetramer is acetylated at Cys89 and has a CoA molecule bound in each of its active-site pockets. CONCLUSIONS: The shape of the substrate-binding pocket reveals the basis for the short-chain substrate specificity of the enzyme. The active-site architecture, and in particular the position of the covalently attached acetyl group, allow a more detailed reaction mechanism to be proposed in which Cys378 is involved in both steps of the reaction. The structure also suggests an important role for the thioester oxygen atom of the acetylated enzyme in catalysis.

The 2.8 A crystal structure of peroxisomal 3-ketoacyl-CoA thiolase of Saccharomyces cerevisiae: a five-layered alpha beta alpha beta alpha structure constructed from two core domains of identical topology.

BACKGROUND: The peroxisomal enzyme 3-ketoacyl-coenzyme A thiolase of the yeast Saccharomyces cerevisiae is a homodimer with 417 residues per subunit. It is synthesized in the cytosol and subsequently imported into the peroxisome where it catalyzes the last step of the beta-oxidation pathway. We have determined the structure of this thiolase in order to study the reaction mechanism, quaternary associations and intracellular targeting of thiolases generally, and to understand the structural basis of genetic disorders associated with human thiolases. RESULTS: Here we report the crystal structure of unliganded yeast thiolase refined at 2.8 A resolution. The enzyme comprises three domains; two compact core domains having the same fold and a loop domain. Each of the two core domains is folded into a mixed five-stranded beta-sheet covered on each side by helices and the two are assembled into a five-layered alpha beta alpha beta alpha structure. The central layer is formed by two helices, which point with their amino termini towards the active site. The loop domain, which is to some extent stabilized by interactions with the other subunit, runs over the surface of the two core domains, encircling the active site of its own subunit. CONCLUSIONS: The crystal structure of thiolase shows that the active site is a shallow pocket, shaped by highly conserved residues. Two conserved cysteines and a histidine at the floor of this pocket probably play key roles in the reaction mechanism. The two active sites are on the same face of the dimer, far from the amino and carboxyl termini of both subunits and the disordered amino-terminal import signal sequence.

The crystal structure of an engineered monomeric triosephosphate isomerase, monoTIM: the correct modelling of an eight-residue loop.

BACKGROUND: The triosephosphate isomerase (TIM) fold is found in several different classes of enzymes, most of which are oligomers; TIM itself always functions as a very tight dimer. It has recently been shown that a monomeric form of TIM ('monoTIM') can be constructed by replacing a 15-residue interface loop, loop-3, with an eight-residue fragment; modelling suggests that this should result in a short strain-free turn, resulting in the subsequent helix, helix-A3, having an additional turn at its amino terminus. RESULTS: The crystal structure of monoTIM shows that it retains the characteristic TIM-barrel (betaalpha)8-fold and that the new loop has a structure very close to that predicted. Two other interface loops, loop-1 and loop-4, which contain the active site residues Lys13 and His95, respectively, show significant changes in structure in monoTIM compared with dimeric wild-type TIM. CONCLUSION: The observed structural differences between monoTIM and wild-type TIM indicate that the dimeric appearance of TIM determines the location and conformation of two of the four catalytic residues.

The crystal structure of dienoyl-CoA isomerase at 1.5 A resolution reveals the importance of aspartate and glutamate sidechains for catalysis.

BACKGROUND: The degradation of unsaturated fatty acids is vital to all living organisms. Certain unsaturated fatty acids must be catabolized via a pathway auxiliary to the main beta-oxidation pathway. Dienoyl-coenzyme A (dienoyl-CoA) isomerase catalyzes one step of this auxiliary pathway, the isomerization of 3-trans,5-cis-dienoyl-CoA to 2-trans,4-trans-dienoyl-CoA, and is imported into both mitochondria and peroxisomes. Dienoyl-CoA isomerase belongs to a family of CoA-binding proteins that share the enoyl-CoA hydratase/isomerase sequence motif. RESULTS: The crystal structure of rat dienoyl-CoA isomerase has been determined at 1.5 A resolution. The fold closely resembles that of enoyl-CoA hydratase and 4-chlorobenzoyl-CoA dehalogenase. Dienoyl-CoA isomerase forms hexamers made up of two trimers. The structure contains a well ordered peroxisomal targeting signal type-1 which is mostly buried in the inter-trimer space. The active-site pocket is deeply buried and entirely hydrophobic, with the exception of the acidic residues Asp176, Glu196 and Asp204. Site-directed mutagenesis of Asp204 revealed that this residue is essential for catalysis. In a molecular modeling simulation, a molecule of 3-trans,5-cis-octadienoyl-CoA was docked into the active site. CONCLUSIONS: The structural data, supported by the mutagenesis data, suggest a reaction mechanism where Glu196 acts as a proton acceptor and Asp204 acts as a proton donor. Asp176 is paired with Glu196 and is important for optimizing the catalytic proton transfer properties of Glu196. In the predicted mode of substrate binding, an oxyanion hole stabilizes the transition state by binding the thioester oxygen. The presence of a buried peroxisomal targeting signal suggests that dienoyl-CoA isomerase is prevented from reaching its hexameric structure in the cytosol.

Three new crystal structures of point mutation variants of monoTIM: conformational flexibility of loop-1, loop-4 and loop-8.

BACKGROUND: Wild-type triosephosphate isomerase (TIM) is a very stable dimeric enzyme. This dimer can be converted into a stable monomeric protein (monoTIM) by replacing the 15-residue interface loop (loop-3) by a shorter, 8-residue, loop. The crystal structure of monoTIM shows that two active-site loops (loop-1 and loop-4), which are at the dimer interface in wild-type TIM, have acquired rather different structural properties. Nevertheless, monoTIM has residual catalytic activity. RESULTS: Three new structures of variants of monoTIM are presented, a double-point mutant crystallized in the presence and absence of bound inhibitor, and a single-point mutant in the presence of a different inhibitor. These new structures show large structural variability for the active-site loops, loop-1, loop-4 and loop-8. In the structures with inhibitor bound, the catalytic lysine (Lys13 in loop-1) and the catalytic histidine (His95 in loop-4) adopt conformations similar to those observed in wild-type TIM, but very different from the monoTIM structure. CONCLUSIONS: The residual catalytic activity of monoTIM can now be rationalized. In the presence of substrate analogues the active-site loops, loop-1, loop-4 and loop-8, as well as the catalytic residues, adopt conformations similar to those seen in the wild-type protein. These loops lack conformational flexibility in wild-type TIM. The data suggest that the rigidity of these loops in wild-type TIM, resulting from subunit-subunit contacts at the dimer interface, is important for optimal catalysis.

Crystallographic analysis of the reaction pathway of Zoogloea ramigera biosynthetic thiolase.

Biosynthetic thiolases catalyze the biological Claisen condensation of two acetyl-CoA molecules to form acetoacetyl-CoA. This is one of the fundamental categories of carbon skeletal assembly patterns in biological systems and is the first step in many biosynthetic pathways including those which generate cholesterol, steroid hormones and ketone body energy storage molecules. High resolution crystal structures of the tetrameric biosynthetic thiolase from Zoogloea ramigera were determined (i) in the absence of active site ligands, (ii) in the presence of CoA, and (iii) from protein crystals which were flash frozen after a short soak with acetyl-CoA, the enzyme's substrate in the biosynthetic reaction. In the latter structure, a reaction intermediate was trapped: the enzyme was found to be acetylated at Cys89 and a molecule of acetyl-CoA was bound in the active site pocket. A comparison of the three new structures and the two previously published thiolase structures reveals that small adjustments in the conformation of the acetylated Cys89 side-chain allow CoA and acetyl-CoA to adopt identical modes of binding. The proximity of the acetyl moiety of acetyl-CoA to the sulfur atom of Cys378 supports the hypothesis that Cys378 is important for proton exchange in both steps of the reaction. The thioester oxygen atom of the acetylated enzyme points into an oxyanion hole formed by the nitrogen atoms of Cys89 and Gly380, thus facilitating the condensation reaction. The interaction between the thioester oxygen atom of acetyl-CoA and His348 assists the condensation step of catalysis by stabilizing a negative charge on the thioester oxygen atom. Our structure of acetyl-CoA bound to thiolase also highlights the importance in catalysis of a hydrogen bonding network between Cys89 and Cys378, which includes the thioester oxygen atom of acetyl-CoA, and extends from the catalytic site through the enzyme to the opposite molecular surface. This hydrogen bonding network is different in yeast degradative thiolase, indicating that the catalytic properties of each enzyme may be modulated by differences in their hydrogen bonding networks.

Prediction of the occurrence of the ADP-binding beta alpha beta-fold in proteins, using an amino acid sequence fingerprint.

An amino acid sequence "fingerprint" has been derived that can be used to test if a particular sequence will fold into a beta alpha beta-unit with ADP-binding properties. It was deduced from a careful analysis of the known three-dimensional structures of ADP-binding beta alpha beta-folds. This fingerprint is in fact a set of 11 rules describing the type of amino acid that should occur at a specific position in a peptide fragment. The total length of this fingerprint varies between 29 and 31 residues. By checking against all possible sequences in a database, it appeared that every peptide, which exactly follows this fingerprint, does indeed fold into an ADP-binding beta alpha beta-unit.

Comparison of the three-dimensional protein and nucleotide structure of the FAD-binding domain of p-hydroxybenzoate hydroxylase with the FAD- as well as NADPH-binding domains of glutathione reductase.

The chain fold of the FAD-binding domain of p-hydroxybenzoate hydroxylase resembles the chain folds of the two nucleotide-binding domains of glutathione reductase. This fold consists of a four-stranded parallel beta-sheet sandwiched between a three-stranded antiparallel beta-sheet and alpha-helices. The nucleotides bind in similar positions relative to this chain fold. The best superposition of the folds has been established and geometrically quantified, giving rise to an equivalencing scheme for 110 residue positions, of which only four residues are identical in all three domains. It is discussed whether this chain fold is also present in a number of other FAD-binding proteins with known sequence. After the second strand of the parallel beta-sheet both FAD-binding domains contain long chain excursions, which make intimate contacts to rather distant parts of the respective molecules. In the environment of the isoalloxazine rings we observe interesting similarities. In both enzymes the si-face of this ring is covered by polypeptide, and only the re-face is accessible for the cofactor NADPH. Furthermore, there is a long alpha-helix in each enzyme, which points with its N-terminal start to the O-2 alpha region of isoalloxazine. These helices are spatially in the same position with respect to the isoalloxazine ring but are at quite different positions along the polypeptide chain. Since they can stabilize a negative charge around O-2 alpha, they may be important for the catalytic processes.

Structure determination of the glycosomal triosephosphate isomerase from Trypanosoma brucei brucei at 2.4 A resolution.

The three-dimensional crystal structure of the enzyme triosephosphate isomerase from the unicellular tropical blood parasite Trypanosoma brucei brucei has been determined at 2.4 A resolution. This triosephosphate isomerase is sequestered in the glycosome, a unique trypanosomal microbody of vital importance for the energy-generating machinery of the trypanosome. The crystals contain one dimer per asymmetric unit. The structure could be solved by the method of molecular replacement, using the refined co-ordinates of chicken triosephosphate isomerase as a search model. The positions and individual isotropic temperature factors of the 3792 atoms of the complete dimer have been refined by the Hendrickson & Konnert restrained refinement procedure. While tight restraints have been maintained on the bonded distances, the R-factor has dropped to 23.2% for 12317 reflections between 6 A and 2.4 A. A total of 0.6 mg of enzyme was used for establishing the correct crystallization conditions and solving the three-dimensional structure. Although the sequences of trypanosomal and chicken triosephosphate isomerase are identical at only 52% of the 247 common positions, the overall folds are very similar. The architecture of the active sites is virtually the same with 85% of the side-chains being identical. On the other hand, the residues involved in the dimer contacts are the same at only 55% of the positions. Nevertheless, the position of the local 2-fold axis in the chicken and glycosomal dimers is similar. A remarkable feature of glycosomal triosephosphate isomerase is its high overall positive charge. This extra charge is concentrated in four clusters of positively charged side-chains on the surface of the dimer, quite far away from the active site. These clusters may be involved in the mechanism of import of this triosephosphate isomerase into the glycosome.

Crystallographic studies of 3-ketoacylCoA thiolase from yeast Saccharomyces cerevisiae.

Good diffracting crystals of 3-ketoacylCoA thiolase (EC 2.3.1.16) from yeast Saccharomyces cerevisiae have been obtained. The crystals diffract to at least 2.4 A. The space group of these crystals is P2(1)2(1)2(1), with cell dimensions a = 71.8 A, b = 93.8 A and c = 119.9 A. There is one dimer per asymmetric unit.

Comparison of the refined crystal structures of liganded and unliganded chicken, yeast and trypanosomal triosephosphate isomerase.

The refined crystal structures of chicken, yeast and trypanosomal triosephosphate isomerase (TIM) have been compared. TIM is known to exist in an "open" (unliganded) and "closed" (liganded) conformation. For chicken TIM only the refined open structure is available, whereas for yeast TIM and trypanosomal TIM refined structures of both the open and the closed structure have been used for this study. Comparison of these structures shows that the open structures of chicken TIM, yeast TIM and trypanosomal TIM are essentially identical. Also it is shown that the closed structures of yeast TIM and trypanosomal TIM are essentially identical. The conformational difference between the open and closed structures concerns a major shift (7 A) in loop-6. Minor shifts are observed in the two adjacent loops, loop-5 (1 A) and loop-7 (1 A). The pairwise comparison of the three different TIM barrels shows that the 105C alpha atoms of the core superimpose within 0.9 A. The sequences of these three TIMs have a pairwise sequence identity of approximately 50%. The residues that line the active site are 100% conserved. The residues interacting with each other across the dimer interface show extensive variability, but the direct hydrogen bonds between the two subunits are well conserved. The orientation of the two monomers with respect to each other is almost identical in the three different TIM structures. There are 56 (22%) conserved residues out of approximately 250 residues in 13 sequences. The functions of most of these conserved residues can be understood from the available open and closed structures of the three different TIMs. Some of these residues are quite far from the active site. For example, at a distance of 19 A from the active site there is a conserved saltbridge interaction between residues at the C-terminal ends of alpha-helix-6 and alpha-helix-7. This anchoring contrasts with the large conformational flexibility of loop-6 and loop-7 near the N termini of these helices. The flexibility of loop-6 is facilitated by a conserved large empty cavity near the N terminus of alpha-helix-6, which exists only in the open conformation.

Preliminary crystallographic studies of triosephosphate isomerase from the blood parasite Trypanosoma brucei brucei.

Crystals of triosephosphate isomerase (EC 5.3.1.1) from Trypanosoma brucei brucei have been grown. These crystals diffract to at least 2 A, even after 60 hours of exposure to X-rays. The space group is P212121, with cell dimensions a = 112.4 A, b = 97.8 A, c = 48.0 A. There is one dimer per asymmetric unit.

Crystallization and preliminary X-ray analysis of the periplasmic fragment of CyoA-a subunit of the Escherichia coli cytochrome o complex.

CyoA, an integral membrane protein, is a subunit of the Escherichia coli cytochrome o quinol oxidase complex. The C-terminal periplasmic domain of CyoA has been expressed in E. coli, purified and crystallized. Crystals were grown using ammonium sulphate as a precipitant. They have space group I222 or I2(1)2(1)2(1) and diffract X-rays to 2.3 A resolution.

Refined 1.83 A structure of trypanosomal triosephosphate isomerase crystallized in the presence of 2.4 M-ammonium sulphate. A comparison with the structure of the trypanosomal triosephosphate isomerase-glycerol-3-phosphate complex.

Triosephosphate isomerase (TIM) is a dimeric glycolytic enzyme. TIM from Trypanosoma brucei brucei has been crystallized at pH 7.0 in 2.4 M-ammonium sulphate. The well-diffracting crystals have one dimer per asymmetric unit. The structure has been refined at 1.83 A resolution with an R-factor of 18.3% for all data between 6 A and 1.83 A (37,568 reflections). The model consists of 3778 protein atoms and 297 solvent atoms. Subunit 1 is involved in considerably more crystal contacts than subunit 2. Correlated with these differences in crystal packing is the observation that only in the active site of subunit 2 is a sulphate ion bound. Furthermore, significant differences with respect to structure and flexibility are observed in three loops near the active site. In particular, there is a 7 A positional difference of the tip of the flexible loop (loop 6) when comparing subunit 1 and subunit 2. Also, the neighbouring loops (loop 5 and loop 7) have significantly different conformations and flexibility. In subunit 1, loop 6 is in an "open" conformation, in subunit 2, loop 6 is in an "almost closed" conformation. Only in the presence of a phosphate-containing ligand, such as glycerol-3-phosphate, does loop 6 take up the "closed" conformation. Loop 6 and loop 7 (and also to some extent loop 5) are rather flexible in the almost closed conformation, but well defined in the open and closed conformations. The closing of loop 6 (167 to 180), as observed in the almost closed conformation, slightly changes the main-chain conformation of the catalytic glutamate, Glu167, leading to a change of the chi 1 angle of this residue from approximately -60 degrees to approximately 60 degrees and the weakening of the hydrogen bonds between its polar side-chain atoms and Ser96. In the closed conformation, in the presence of glycerol-3-phosphate, the main-chain atoms of Glu167 remain in the same position as in the almost closed conformation, but the side-chain has rotated around the CA-CB bond changing chi 1 from approximately 60 degrees to approximately -60 degrees. In this new position the hydrogen bonding to Ser96 is completely lost and also a water-mediated salt bridge between OE2(Glu167) and NE(Arg99) is lost. Comparison of the two independently refined subunits, showed that the root-mean-square deviation for all 249 CA atoms is 0.9 A; for the CA atoms of the beta-strands this is only 0.2 A. The average B-factor for all subunit 1 and subunit 2 atoms is 20 A2 and 25 A2, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

The crystal structure of delta(3)-delta(2)-enoyl-CoA isomerase.

The active-site geometry of the first crystal structure of a Delta(3)-Delta(2)-enoyl-coenzyme A (CoA) isomerase (the peroxisomal enzyme from the yeast Saccharomyces cerevisiae) shows that only one catalytic base, Glu158, is involved in shuttling the proton from the C2 carbon atom of the substrate, Delta(3)-enoyl-CoA, to the C4 atom of the product, Delta(2)-enoyl-CoA. Site-directed mutagenesis has been performed to confirm that this glutamate residue is essential for catalysis. This Delta(3)-Delta(2)-enoyl-CoA isomerase is a hexameric enzyme, consisting of six identical subunits. It belongs to the hydratase/isomerase superfamily of enzymes which catalyze a wide range of CoA-dependent reactions. The members of the hydratase/ isomerase superfamily have only a low level of sequence identity. Comparison of the crystal structure of the Delta(3)-Delta(2)-enoyl-CoA isomerase with the other structures of this superfamily shows only one region of large structural variability, which is in the second turn of the spiral fold and which is involved in defining the shape of the binding pocket.

The crystal structure of enoyl-CoA hydratase complexed with octanoyl-CoA reveals the structural adaptations required for binding of a long chain fatty acid-CoA molecule.

The structure of the hexameric rat mitochondrial enoyl-Coenzyme A (CoA) hydratase, co-crystallised with the inhibitor octanoyl-CoA, has been refined at a resolution of 2.4 A. Enoyl-CoA hydratase catalyses the hydration of 2,3-unsaturated enoyl-CoA thioesters. In the crystal structure only four of the six active sites of the hexamer in the asymmetric unit are occupied with a ligand molecule, showing an unliganded and a liganded active site within the same crystal form. While the protein assembly and fold is identical to the previously solved acetoacetyl-CoA complex, differences are observed close to the fatty acid binding pocket due to the different nature of the ligands. The fatty acid tail of octanoyl-CoA is bound in an extended conformation. This is possible because a high B-factor loop, which separates in the acetoacetyl-CoA complex the binding pocket of the acetoacetyl-CoA fatty acid tail from the intertrimer space, has moved aside to allow binding of the longer octanoyl-CoA moiety. The movement of this loop opens a tunnel which traverses the complete subunit from the solvent space to the intertrimer space. The conformation of the catalytic residues is identical, in both structures as well as in the liganded and the unliganded active sites. In the unliganded active sites a water molecules is bound between the two catalytic glutamate, residues Glu144 and Glu164. After superposition of a liganded active site on an unliganded active site this water molecule is close to the carbon centre that becomes hydroxylated in the hydratase reaction. These findings support the idea that the active site is rigid and that the catalytic residues and the water molecule, as seen in the unliganded active site, are pre-positioned for very efficient catalysis.