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Riboflavin synthase catalyzes the final step in the biosynthesis of riboflavin. Animals and humans lack this enzyme, whereas many bacteria and certain yeasts are absolutely dependent on endogenous riboflavin synthesis. Riboflavin synthase is therefore an attractive target for chemotherapy. The N-terminal domain of riboflavin synthase forms a dimer in solution and is capable of strongly binding riboflavin. It can serve as a model for the binding site of the native enzyme. Structural information obtained from this domain at high resolution will be helpful in the determination of the binding mode of riboflavin and thus for the development of antimicrobial drugs. Here, the crystallization and preliminary crystallographic analysis of the N-terminal domain of riboflavin synthase are reported. The crystals belong to the space group C222(1), with unit-cell parameters a = 50.3, b = 104.7, c = 85.3 A, alpha = beta = gamma = 90 degrees, and diffract to 2.6 A resolution.

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An open reading frame optimized for expression of 6,7-dimethyl-8-ribityl-lumazine synthase of the hyperthermophilic bacterium Aquifex aeolicus in Escherichia coli was synthesized and expressed in a recombinant E. coli strain to a level of around 15 %. The recombinant protein was purified by heat-treatment and gel-filtration. The protein was crystallized in the cubic space group I23 with the cell dimensions a = b = c = 180.8 A, and diffraction data were collected to 1.6 A resolution. The structure was solved by molecular replacement using lumazine synthase from Bacillus subtilis as search model. The structure of the A. aeolicus enzyme was refined to a resolution of 1.6 A. The spherical protein consists of 60 identical subunits with strict icosahedral 532 symmetry. The subunit fold is closely related to that of the B. subtilis enzyme (rmsd 0.80 A). The extremely thermostable lumazine synthase from A. aeolicus has a melting temperature of 119.9 degrees C. Compared to other icosahedral and pentameric lumazine synthases, the A. aeolicus enzyme has the largest accessible surface presented by charged residues and the smallest surface presented by hydrophobic residues. It also has the largest number of ion-pairs per subunit. Two ion-pair networks involving two, respectively three, stacking arginine residues assume a distinct role in linking adjacent subunits. The findings indicate the influence of the optimization of hydrophobic and ionic contacts in gaining thermostability.

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Lumazine synthase of Saccharomyces cerevisiae is a homopentamer with a molecular weight of 90 kDa. Crystals of the recombinant enzyme with a size of up to 1.6 mm were obtained. The space group is P4(1)2(1)2 with lattice dimensions 82.9 A x 82.9 A x 300.2 A. X-ray diffraction data collected under cryogenic conditions were complete to 1.85 A resolution. The structure of the enzyme in complex with the intermediate analogue, 5-(6-D-ribitylamino-2,4-dihydroxypyrimidine-5-yl)-1-pentyl-p hosphonic acid was solved via molecular replacement using the structure of the Bacillus subtilis enzyme as search model and was refined to a final R-factor of 19.8% (Rfree: 22.5%). The conformation of the active site ligand of the enzyme mimicks that of the Schiff base intermediate of the enzyme-catalyzed reaction. The data enable the reconstruction of the reactant topology during the early steps of the catalytic reaction. Structural determinants, which are likely to be responsible for the inability of the S. cerevisiae enzyme to form icosahedral capsids, will be discussed.

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Riboflavin synthase is a trimer of identical 23-kDa subunits. The primary structure is characterized by considerable similarity of the C-terminal and N-terminal parts. Recombinant riboflavin synthase of Escherichia coli and Bacillus subtilis was crystallized by the vapor diffusion method. Crystals of E. coli riboflavin synthase belong to the orthorhombic system, space group P2(1)2(1)2(1), with unit cell dimensions a = 53.2 A, b = 117.6 A, c = 150.9 A, alpha = beta = gamma = 90 degrees. They diffract to better than 3.3 A resolution and have presumably one trimer in the asymmetric unit. The self rotation function indicates local 32 symmetry. Twofold local symmetry is an unexpected result in a trimeric protein. In conjunction with primary structure arguments and mechanistic considerations, we propose that the protein is a pseudohexamer where each of the peptide subunits fold into two topologically similar domains.

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GTP cyclohydrolase I of Escherichia coli is a torus-shaped homodecamer with D5 symmetry and catalyzes a complex ring expansion reaction conducive to the formation of dihydroneopterin triphosphate from GTP. The x-ray structure of a complex of the enzyme with the substrate analog, dGTP, bound at the active site was determined at a resolution of 3 A. In the decamer, 10 equivalent active sites are present, each of which contains a 10-A deep pocket formed by surface areas of 3 adjacent subunits. The substrate forms a complex hydrogen bond network with the protein. Active site residues were modified by site-directed mutagenesis, and enzyme activities of the mutant proteins were measured. On this basis, a mechanism of the enzyme-catalyzed reaction is proposed. Cleavage of the imidazole ring is initiated by protonation of N7 by His-179 followed by the attack of water at C8 of the purine system. Cystine Cys-110 Cys-181 may be involved in this reaction step. Opening of the imidazole ring may be in concert with cleavage of the furanose ring to generate a Schiff's base from the glycoside. The gamma-phosphate of GTP may be involved in the subsequent Amadori rearrangement of the carbohydrate side chain by activating the hydroxyl group of Ser-135.

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A monoclinic crystal modification of GTP cyclohydrolase I (space group P2(1), a = 204.2 A, b = 210.4 A, c = 71.8 A, alpha = gamma = 90 degrees, beta = 95.8 degrees) was studied by freeze-etching electron microscopy and by Patterson correlation techniques. The freeze-etched samples were either shadowed with Pt/C or decorated with monolayers of gold, silver or platinum. Correlation averaged electron micrographs of decoration replicas indicated 5-fold molecular symmetry. In conjunction with the molecular mass of the active GTP cyclohydrolase I enzyme complex of about 210,000 Da, which had been reported in the literature, and a molecular mass of the protomers of 24,700 Da, the electron microscopic observation suggests that the enzyme is a decamer with 5-fold symmetry. The processed images of decorated crystal surfaces also showed that the four protein multimers in the crystal unit cell are related by 4-fold pseudosymmetry. A Patterson analysis of the X-ray data showed two non-crystallographic 5-fold axes, inclined at 12 degrees to each other, thus confirming and extending the electron microscopic findings. Additionally, local 2-fold axes were found in planes perpendicular to the 5-fold particle axes. Thus, the combined X-ray and electron microscope data indicate that GTP cyclohydrolase I is a decamer with D5 symmetry. A procedure for hkl assignments of the crystal planes observed in electron micrographs was developed. On this basis, it was possible to determine the approximate molecular positions in the ab plane. Independent information on the crystal packing was obtained by single isomorphous replacement and electron density averaging. The 5-fold averaged 6 A electron density shows that the GTP cyclohydrolase I decamer is torus-shaped with an approximate diameter of 100 A and a thickness of 65 A. The study demonstrates that the combination of freeze-etching electron microscopy with Patterson analysis of X-ray data is a powerful approach for the solution of complex crystallographic problems. The procedure for this analysis as well as possible pitfalls are discussed in detail.

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BACKGROUND: Tetrahydrobiopterin serves as the cofactor for enzymes involved in neurotransmitter biosynthesis and as regulatory factor in immune cell proliferation and the biosynthesis of melanin. The biosynthetic pathway to tetrahydrobiopterin consists of three steps starting from GTP. The initial reaction is catalyzed by GTP cyclohdrolase I (GTP-CH-I) and involves the chemically complex transformation of the purine into the pterin ring system. RESULTS: The crystal structure of the Escherichia coli GTP-CH-I was solved by single isomorphous replacement and molecular averaging at 3.0 A resolution. The functional enzyme is a homodecameric complex with D5 symmetry, forming a torus with dimensions 65 A x 100 A. The pentameric subunits are constructed via an unprecedented cyclic arrangement of the four-stranded antiparallel beta-sheets of the five monomers to form a 20-stranded antiparallel beta-barrel of 35 A diameter. Two pentamers are tightly associated by intercalation of two antiparallel helix pairs positioned close to the subunit N termini. The C-terminal domain of the GTP-CH-I monomer is topologically identical to a subunit of the homohexameric 6-pyruvoyl tetrahydropterin synthase, the enzyme catalyzing the second step in tetrahydrobiopterin biosynthesis. CONCLUSIONS: The active site of GTP-CH-I is located at the interface of three subunits. It represents a novel GTP-binding site, distinct from the one found in G proteins, with a catalytic apparatus that suggest involvement of histidines and, possibly, a cystine in the unusual reaction mechanism. Despite the lack of significant sequence homology between GTP-CH-I and 6-pyruvoyl tetrahydropterin synthase, the two proteins, which catalyze consecutive steps in tetrahydrobiopterin biosynthesis, share a common subunit fold and oligomerization mode. In addition, the active centres have an identical acceptor site for the 2-amino-4-oxo pyrimidine moiety of their substrates which suggests an evolutionarily conserved protein fold designed for pterin biosynthesis.

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