Preliminary crystallographic study of a complex formed between the alpha/beta-tubulin heterodimer and the neuronal growth-associated protein SCG10.

Crystals of a complex formed between the alpha/beta-tubulin heterodimer and SCG10, a neuron-specific growth-associated protein, have been obtained by the hanging drop method. They belong to the space group P2(1)2(1)2(1), with unit cell parameters a = 56 A, b = 353 A, c = 466 A and four molecular complexes in the asymmetric unit. A complete X-ray diffraction data set to 6.1 A resolution has been collected using synchrotron radiation. This represents a challenging opportunity to study at a molecular level the structure-function relationships between a microtubule-destabilizing protein, SCG10, and tubulin.

Interaction between the lipoamide-containing H-protein and the lipoamide dehydrogenase (L-protein) of the glycine decarboxylase multienzyme system 2. Crystal structures of H- and L-proteins.

The glycine decarboxylase complex consists of four different component enzymes (P-, H-, T- and L-proteins). The 14-kDa lipoamide-containing H-protein plays a pivotal role in the complete sequence of reactions as its prosthetic group (lipoic acid) interacts successively with the three other components of the complex and undergoes a cycle of reductive methylamination, methylamine transfer and electron transfer. With the aim to understand the interaction between the H-protein and its different partners, we have previously determined the crystal structure of the oxidized and methylaminated forms of the H-protein. In the present study, we have crystallized the H-protein in its reduced state and the L-protein (lipoamide dehydrogenase or dihydrolipoamide dehydrogenase). The L-protein has been overexpressed in Escherichia coli and refolded from inclusion bodies in an active form. Crystals were obtained from the refolded L-protein and the structure has been determined by X-ray crystallography. This first crystal structure of a plant dihydrolipoamide dehydrogenase is similar to other known dihydrolipoamide dehydrogenase structures. The crystal structure of the H-protein in its reduced form has been determined and compared to the structure of the other forms of the protein. It is isomorphous to the structure of the oxidized form. In contrast with methylaminated H-protein where the loaded lipoamide arm was locked into a cavity of the protein, the reduced lipoamide arm appeared freely exposed to the solvent. Such a freedom is required to allow its targeting inside the hollow active site of L-protein. Our results strongly suggest that a direct interaction between the H- and L-proteins is not necessary for the reoxidation of the reduced lipoamide arm bound to the H-protein. This hypothesis is supported by biochemical data [Neuburger, M., Polidori, A.M., Piètre, E., Faure, M., Jourdain, A., Bourguignon, J., Pucci, B. & Douce, R. (2000) Eur. J. Biochem. 267, 2882-2889] and by small angle X-ray scattering experiments reported herein.

The crystal structure of the minus-end-directed microtubule motor protein ncd reveals variable dimer conformations.

BACKGROUND: The kinesin superfamily of microtubule-associated motor proteins are important for intracellular transport and for cell division in eukaryotes. Conventional kinesins have the motor domain at the N terminus of the heavy chain and move towards the plus end of microtubules. The ncd protein is necessary for chromosome segregation in meiosis. It belongs to a subfamily of kinesins that have the motor domain at the C terminus and move towards the minus end of microtubules. RESULTS: The crystal structure of dimeric ncd has been obtained at 2.9 A resolution from crystals with the C222(1) space group, with two independent dimers per asymmetric unit. The motor domains in these dimers are not related by crystallographic symmetry and the two ncd dimers have significantly different conformations. An alpha-helical coiled coil connects, and interacts with, the motor domains. CONCLUSIONS: The ncd protein has a very compact structure, largely due to extended interactions of the coiled coil with the head domains. Despite this, we find that the overall conformation of the ncd dimer can be rotated by as much as 10 degrees away from that of the twofold-symmetric archetypal ncd. The crystal structures of conventional kinesin and of ncd suggest a structural rationale for the reversal of the direction of movement in chimeric kinesins.

Crystal structure of Pseudomonas fluorescens 4-hydroxyphenylpyruvate dioxygenase: an enzyme involved in the tyrosine degradation pathway.

BACKGROUND: In plants and photosynthetic bacteria, the tyrosine degradation pathway is crucial because homogentisate, a tyrosine degradation product, is a precursor for the biosynthesis of photosynthetic pigments, such as quinones or tocophenols. Homogentisate biosynthesis includes a decarboxylation step, a dioxygenation and a rearrangement of the pyruvate sidechain. This complex reaction is carried out by a single enzyme, the 4-hydroxyphenylpyruvate dioxygenase (HPPD), a non-heme iron dependent enzyme that is active as a homotetramer in bacteria and as a homodimer in plants. Moreover, in humans, a HPPD deficiency is found to be related to tyrosinemia, a rare hereditary disorder of tyrosine catabolism. RESULTS: We report here the crystal structure of Pseudomonas fluorescens HPPD refined to 2.4 A resolution (Rfree 27.6%; R factor 21.9%). The general topology of the protein comprises two barrel-shaped domains and is similar to the structures of Pseudomonas 2,3-dihydroxybiphenyl dioxygenase (DHBD) and Pseudomonas putida catechol 2,3-dioxygenase (MPC). Each structural domain contains two repeated betaalpha betabeta betaalpha modules. There is one non-heme iron atom per monomer liganded to the sidechains of His161, His240, Glu322 and one acetate molecule. CONCLUSIONS: The analysis of the HPPD structure and its superposition with the structures of DHBD and MPC highlight some important differences in the active sites of these enzymes. These comparisons also suggest that the pyruvate part of the HPPD substrate (4-hydroxyphenylpyruvate) and the O2 molecule would occupy the three free coordination sites of the catalytic iron atom. This substrate-enzyme model will aid the design of new inhibitors of the homogentisate biosynthesis reaction.

The crystal structure of a wheat nonspecific lipid transfer protein (ns-LTP1) complexed with two molecules of phospholipid at 2.1 A resolution.

Nonspecific lipid transfer proteins (ns-LTP1) form a multigenic protein family in plants. In vitro they are able to bind all sort of lipids but their function, in vivo, remains speculative. A ns-LTP1 isolated from wheat seed was crystallized in the presence of lyso-myristoyl-phosphatidylcholine (LMPC). The structure was solved by molecular replacement and refined to 2.1 A resolution to an R-factor of 16.3% and a free R-factor of 21.3%. It reveals for the first time that the protein binds two LMPC molecules that are inserted head to tail in a hydrophobic cavity. A detailed study of the structure leads to the conclusion that there are two lipid-binding sites, one of which shows a higher affinity for the LMPC than the other. Comparison with other structures of lipid-bound ns-LTP1 suggests that the presence of two binding sites is a general feature of plant ns-LTP1.

The crystal structure of plant acetohydroxy acid isomeroreductase complexed with NADPH, two magnesium ions and a herbicidal transition state analog determined at 1.65 A resolution.

Acetohydroxy acid isomeroreductase catalyzes the conversion of acetohydroxy acids into dihydroxy valerates. This reaction is the second in the synthetic pathway of the essential branched side chain amino acids valine and isoleucine. Because this pathway is absent from animals, the enzymes involved in it are good targets for a systematic search for herbicides. The crystal structure of acetohydroxy acid isomeroreductase complexed with cofactor NADPH, Mg2+ ions and a competitive inhibitor with herbicidal activity, N-hydroxy-N-isopropyloxamate, was solved to 1.65 A resolution and refined to an R factor of 18.7% and an R free of 22.9%. The asymmetric unit shows two functional dimers related by non-crystallographic symmetry. The active site, nested at the interface between the NADPH-binding domain and the all-helical C-terminus domain, shows a situation analogous to the transition state. It contains two Mg2+ ions interacting with the inhibitor molecule and bridged by the carboxylate moiety of an aspartate residue. The inhibitor-binding site is well adjusted to it, with a hydrophobic pocket and a polar region. Only 24 amino acids are conserved among known acetohydroxy acid isomeroreductase sequences and all of these are located around the active site. Finally, a 140 amino acid region, present in plants but absent from other species, was found to make up most of the dimerization domain.

Structural studies of the glycine decarboxylase complex from pea leaf mitochondria.

The glycine decarboxylase complex consists of four different component enzymes (P-, H-, T- and L-proteins). The 14-kDa lipoamide-containing H-protein plays a pivotal role in the complete sequence of reactions since its prosthetic group (lipoic acid) interacts successively with the three other components of the complex and undergoes a cycle of reductive methylamination, methylamine transfer and electron transfer. The X-ray crystal structure of different forms of the H-protein has shown a unique conformation of the protein. This leads to the hypothesis of a three-dimensional recognition of the H-protein by the other components of the system and also by the ligase which lipoylates the H-protein. Striking structural similarities are observed between the H-protein and other lipoate domains of 2-oxo acid dehydrogenases and with the biotin carrier protein of acetyl-CoA carboxylase. In the H-protein, the lipoamide arm is free to move in the solvent when oxidized but is pivoted and tightly bound into a cleft at the protein surface when methylamine-loaded. This implies that the H-protein and the T-component form a stable complex during the catalytic transfer of the methylene unit to the tetrahydrofolate cofactor of the T-protein. This complex has been detected by small angle scattering experiments. In conclusion, in the glycine decarboxylase system, the lipoamide arm does not swing freely from one catalytic site to another as was proposed in other systems.

Expression, lipoylation and structure determination of recombinant pea H-protein in Escherichia coli.

A synthetic gene encoding the entire mature H protein of the glycine decarboxylase complex from pea (Pisum sativum L.) was constructed and expressed in Escherichia coli. The recombinant H protein, which after the induction period constituted more than half of the E. coli protein, was found in a soluble form. Activity measurements and mass-spectrometry analysis of the purified protein showed that, in the absence or presence of 5[3-(1,2)-dithiolanyl]pentanoic acid (lipoic acid) in the culture medium, recombinant H protein could be produced as the unlipoylated apoform or as the lipoylated form, respectively. Addition of chloramphenicol to the culture medium after induction increased the proportion of lipoylated H protein. High rates of lipoylation of the H apoprotein were measured in vivo and in vitro, revealing that the recombinant pea H protein was an excellent substrate for the E. coli lipoyl-ligase. The three-dimensional structure of the recombinant H apoprotein was determined at a 0.25-nm resolution. It was almost identical to the structure of the native pea leaf enzyme, which indicates that the recombinant protein folds properly in E. coli and that the lipoyl-ligase recognizes a three-dimensional structure in order to add lipoic acid to its specific lysine residue. It is postulated that the high level of expression and lipoylation of recombinant H protein may be due to the protein retaining the structure of the original enzyme.

Refined structures at 2 and 2.2 A resolution of two forms of the H-protein, a lipoamide-containing protein of the glycine decarboxylase complex.

H-protein, a 14 kDa lipoic acid-containing protein is a component of the glycine decarboxylase complex. This complex which consists of four protein components (P-, H-, T- and L-protein) catalyzes the oxidative decarboxylation of glycine. The mechanistic heart of the complex is provided by the lipoic acid attached to a lysine residue of the H-protein. It undergoes a cycle of transformations, i.e. reductive methylamination, methylamine transfer, and electron transfer. We present details of the crystal structures of the H-protein, in its two forms, H-Pro(Ox) with oxidized lipoamide and H-Pro(Met) with methylamine-loaded lipoamide. X-ray diffraction data were collected from crystals of H-Pro(Ox) to 2 and H-Pro(Met) to 2.2 A resolution. The final R-factor value for the H-Pro(Ox) is 18.5% for data with F > 2sigma. in the range of 8.0-2.0 A resolution. The refinement confirmed our previous model, refined to 2.6 A, of a beta-fold sandwich structure with two beta-sheets. The lipoamide arm attached to Lys63, located in the loop of a hairpin conformation, is clearly visible at the surface of the protein. The H-Pro(Met) has been crystallized in orthorhombic and monoclinic forms and the structures were solved by molecular replacement, starting from the H-Pro(Ox) model. The orthorhombic structure has been refined with a final R-factor value of 18.5% for data with F > 2sigma in the range of 8.0-2.2 A resolution. The structure of the monoclinic form has been refined with a final R-factor value of 17.5% for data with F > 2sigma in the range of 15.0-3.0 A. In these two structures which have similar packing, the protein conformation is identical to the conformation found in the H-Pro(Ox). The main change lies in the position of the lipoamide group which has moved significantly when loaded with methylamine. In this case the methylamine-lipoamide group is tucked into a cleft at the surface of the protein where it is stabilized by hydrogen bonds and hydrophobic contacts. Thus, it is totally protected and not free to move in aqueous solvent. In addition, the H-protein presents some sequence and structural analogies with other lipoate- and biotin-containing proteins and also with proteins of the phosphoenolpyruvate:sugar phosphotransferase system.

The lipoamide arm in the glycine decarboxylase complex is not freely swinging.

Glycine decarboxylase consists of four protein components. Its structural and mechanistic heart is provided by the lipoic acid-containing H-protein which undergoes a cycle of reductive methylamination, methylamine transfer and electron transfer. Lipoic acid attached to a specific lysine side chain is assumed to act as a 'swinging arm' conveying the reactive dithiolane ring from one catalytic centre to another. The X-ray crystal structures of two forms of the H-protein have been determined. The lipoate cofactor is located in the loop of a hairpin configuration but following methylamine transfer it is pivoted to bind into a cleft at the surface of the H-protein. The lipoamide-methylamine arm is, therefore, not free to move in aqueous solvent.

Crystallization and preliminary crystallographic data for acetohydroxy acid isomeroreductase from Spinacia oleracea.

Acetohydroxy acid isomeroreductase (EC 1.1.1.86) is one of the enzymes involved in branched-chain amino acid biosynthesis. The enzyme from spinach (Spinacia oleracea) leaves has been crystallized using the hanging drop vapour diffusion method. The free enzyme crystallized from polymethylene glycol solutions, but these crystals were unsuitable for X-ray diffraction analysis. In the presence of NADPH, Mg(2+) and a reaction intermediate analogue (2-dimethylphosphinoyl-2-hydroxy acetic acid (Hoe 704) or N-hydroxy-N-isopropyloxamate (IpOHA)), much better crystals were obtained. Crystals grown from ammonium sulphate belong to space group P2(1) with cell dimensions a + 193.78(7) A, b = 63.69(2) A, c = 112.84(1) A and beta = 121.22(1) degrees. The molecular mass of the protein, the volume of the unit cell, and crystal density measurements indicated that the asymmetric unit contains two dimers. X-ray diffraction patterns showed measurable reflections to beyond 2.5 A.

X-ray structure determination at 2.6-A resolution of a lipoate-containing protein: the H-protein of the glycine decarboxylase complex from pea leaves.

H-protein, a lipoic acid-containing protein of the glycine decarboxylase (EC 1.4.4.2) complex from pea (Pisum sativum) was crystallized from ammonium sulfate solution at pH 5.2 in space group P3(1)21. The x-ray crystal structure was determined to 2.6-A resolution by multiple isomorphous replacement techniques. The structure was refined to an R value of 23% for reflections between 15- and 2.6-A resolution (F > 2 sigma), including the lipoate moiety and 50 water molecules, for the two protein molecules of the asymmetric unit. The 131-amino acid residues form seven beta-strands arranged into two antiparallel beta-sheets forming a "sandwich" structure. One alpha-helix is observed at the C-terminal end. The lipoate cofactor attached to Lys-63 is located in the loop of a hairpin configuration. The lipoate moiety points toward the residues His-34 and Asp-128 and is situated at the surface of the H-protein. This allows the flexibility of the lipoate arm. This is the first x-ray determination of a lipoic acid-containing protein, and the present results are in agreement with previous theoretical predictions and NMR studies of the catalytic domains of lipoic acid- and biotin-containing proteins.

Crystal structure of hydrophobic protein from soybean; a member of a new cysteine-rich family.

X-ray diffraction methods have been used to determine the structure of the 8.3 kDa hydrophobic protein from soybean and to refine the atomic co-ordinates to a crystallographic R-factor of 18.7% at 1.8 A resolution. The molecule is a four-helix bundle, which together with the connecting loops and a twisted beta-strand form a spiral. The surface contains 70% apolar atoms, and the crystal packing is dominated by hydrophobic interactions, producing a two-dimensional sheet of protein molecules. Most of the 59 water molecules located are involved in hydrophilic contacts and their structural organization does not seem to be affected by the high hydrophobicity of the molecule. From the protein fold it appears that three of the four disulphide bridges are important for keeping the amino and carboxyl-terminal segments in place in the native form, while the central part of the molecule is stabilized by many hydrophobic interactions. Although the protein function is not known, a number of possibilities can be excluded on experimental grounds and by comparison with other members of the family.

Crystallographic data for the 9000 dalton wheat non-specific phospholipid transfer protein.

The wheat non-specific phospholipid transfer protein belongs to a family of small proteins sharing a common pattern of four disulphide bridges. Its function in vivo is not known, but it has a high affinity to phospholipids and is involved in phospholipid transfer in vitro. The molecular weight is 9607, and it crystallizes in the space group P2(1) with a = 40.73 A, b = 112.11 A, c = 50.44 A and beta = 106.80 degrees. The crystals diffract to 3 A resolution.

Structure and RNA content of the prosomes.

Duck erythroblasts prosomes were analysed by small angle neutron scattering (SANS), dynamic light scattering and (cryo-)electron microscopy. A molecular weight of approximately 720,000 +/- 50,000, a radius of gyration of 64 +/- 2 A and a hydrodynamic radius of approximately 86 A were obtained. Electron micrographs show a hollow cylinder-like particle with a diameter of 120 A, a height of 170 A and a diameter of 40 A for the cavity, built of four discs, the two outer ones being more pronounced than those in the center. Results from SANS indicate less then 5% of RNA in the purified prosomes, but nuclease protection assays confirm its presence.

Crystallographic data for H-protein from the glycine decarboxylase complex.

The H-protein is the pivotal enzyme of the glycine decarboxylase complex responsible for the oxidation of glycine by mitochondria. It has been extracted and purified from pea leaf mitochondria (Pisum sativum). Its molecular weight, based on the amino acid sequence, is 13.3 kDa and it crystallizes in the space group P3(1)21 (or its enantiomorph P3(2)21) with a = b = 57.14 (3) A, c = 137.11 (11) A. The crystals diffract until at least 3.5 A resolution.

Crystallographic data for soybean hydrophobic protein.

The soybean hydrophobic protein belongs to a family of proteins that contains a number of storage and phospholipid binding proteins. Its function is not known, but its overall hydrophobic nature is typical of many membrane proteins of similar size. The molecular weight is 8.3 x 10(3), and it crystallizes in the space group P2(1)2(1)2(1), with a = 52.01 A, b = 43.50 A and c = 28.80 A. The crystals diffract to 1.8 A resolution, and are thus suitable for X-ray structural studies.

GABA transaminase inhibitors.

In summary, several branched-chain fatty acids appeared to be competitive inhibitors of GABA-T and non-competitive inhibitors of SSADH. These compounds produce an increase in brain GABA level, and for two of these it was shown that the increase differs among various brain areas. An increase of GABA cannot be obtained by inhibition of SSADH. The increase in brain GABA seems to correlate with the anticonvulsant activity of branched-chain fatty acids.