Crystal structure of an early protein-RNA assembly complex of the signal recognition particle.

The signal recognition particle (SRP) is a universally conserved ribonucleoprotein complex that mediates the cotranslational targeting of secretory and membrane proteins to cellular membranes. A crucial early step in SRP assembly in archaea and eukarya is the binding of protein SRP19 to specific sites on SRP RNA. Here we report the 1.8 angstrom resolution crystal structure of human SRP19 in complex with its primary binding site on helix 6 of SRP RNA, which consists of a stem-loop structure closed by an unusual GGAG tetraloop. Protein-RNA interactions are mediated by the specific recognition of a widened major groove and the tetraloop without any direct protein-base contacts and include a complex network of highly ordered water molecules. A model of the assembly of the SRP core comprising SRP19, SRP54, and SRP RNA based on crystallographic and biochemical data is proposed.

Herbicide binding in the bacterial photosynthetic reaction center.

The ureas and phenolics are two major classes of herbicides that act on Photosystem II (PSII) and are normally inactive in the photosynthetic reaction centers of purple bacteria. However, the triazine-resistant mutant T4 from Rhodopseudomonas (Rps.) viridis, which has the tyrosine residue at position 222 on the L subunit substituted for phenylalanine (TyrL222Phe), is sensitive to both ureas and phenolics. Since for the first time structural data on urea binding are available, T4 is a particularly interesting model for the herbicide-binding site of PSII.

Two-dimensional structure of light harvesting complex II (LHII) from the purple bacterium Rhodovulum sulfidophilum and comparison with LHII from Rhodopseudomonas acidophila.

BACKGROUND: Within the membranes of photosynthetic bacteria, up to three types of light harvesting complexes (LHI, LHII, LHIII) are found. These complexes absorb photons and transfer the excitation energy to the photosynthetic reaction centre. The LH complexes comprise units that contain alpha and beta polypeptides with associated pigment molecules. RESULTS: The structure of LHII complex from Rhodovulum sulfidophilum has been examined to a resolution of 7 A using electron microscopy. The complex is a nonamer containing nine alphabeta subunits. These are arranged in two radially symmetric concentric cylinders, with the nine alpha chains positioned in the inner cylinder and the nine beta chains forming the outer cylinder. The 18 transmembrane helices are readily observed in the projection maps, along with 18 additional peaks attributed to the pigment molecules. CONCLUSIONS: The determination of more structures of LH complexes will uncover the full extent of the variability of the oligomerization states in different bacteria and also in the native membrane. The analysis of two-dimensional crystals allows a rapid determination of key structural features and the oligomeric state of the complex. Comparison of our structure determined by electron microscopy with the recently solved X-ray structure indicates that the results of the two methods are complementary.

The crystal structure of the conserved GTPase of SRP54 from the archaeon Acidianus ambivalens and its comparison with related structures suggests a model for the SRP-SRP receptor complex.

BACKGROUND: Protein targeting to the endoplasmic reticulum in eukaryotes and to the cell membrane in prokaryotes is mediated by the signal recognition particle (SRP) and its receptor (SR). Both contain conserved GTPase domains in the signal-peptide-binding proteins (SRP54 and Ffh) and the SR proteins (SRalpha and FtsY). These GTPases are involved in the regulation of protein targeting. Most studies so far have focussed on the SRP machinery of mammals and bacteria, leaving the SRP system of archaea less well understood. RESULTS: We report the crystal structure of the conserved GTPase (NG-Ffh) from the thermophilic archaeon Acidianus ambivalens at 2.0 A resolution and of the Thr112-->Ala mutant, which is inactive in GTP hydrolysis. This is the first structure of an SRP component from an archaeon and allows for a detailed comparison with related structures from Escherichia coli and thermophilic bacteria. In particular, differences in the conserved consensus regions for nucleotide binding and the subdomain interfaces are observed, which provide information about the regulation of the GTPase. These interactions allow us to propose a common signalling mechanism for the SRP-SR system. CONCLUSIONS: The overall structure of SRP-GTPases is well conserved between bacteria and archaea, which indicates strong similarities in the regulation of the SRP-targeting pathway. Surprisingly, structure comparisons identified a homodimeric ATP-binding protein as the closest relative. A heterodimer model for the SRP-SR interaction is presented.

Crystal structure of phosphoadenylyl sulphate (PAPS) reductase: a new family of adenine nucleotide alpha hydrolases.

BACKGROUND: Assimilatory sulphate reduction supplies prototrophic organisms with reduced sulphur for the biosynthesis of all sulphur-containing metabolites. This process is driven by a sequence of enzymatic steps involving phosphoadenylyl sulphate (PAPS) reductase. Thioredoxin is used as the electron donor for the reduction of PAPS to phospho-adenosine-phosphate (PAP) and sulphite. Unlike most electron-transfer reactions, there are no cofactors or prosthetic groups involved in this reduction and PAPS reductase is one of the rare examples of an enzyme that is able to store two electrons. Determination of the structure of PAPS reductase is the first step towards elucidating the biochemical details of the reduction of PAPS to sulphite. RESULTS: We have determined the crystal structure of PAPS reductase at 2.0 A resolution in the open, reduced form, in which a flexible loop covers the active site. The protein is active as a dimer, each monomer consisting of a central six-stranded beta sheet with alpha helices packing against each side. A highly modified version of the P loop, the fingerprint peptide of mononucleotide-binding proteins, is present in the active site of the protein, which appears to be a positively charged cleft containing a number of conserved arginine and lysine residues. Although PAPS reductase has no ATPase activity, it shows a striking similarity to the structure of the ATP pyrophosphatase (ATP PPase) domain of GMP synthetase, indicating that both enzyme families have evolved from a common ancestral nucleotide-binding fold. CONCLUSIONS: The sequence conservation between ATP sulphurylases, a subfamily of ATP PPases, and PAPS reductase and the similarities in both their mechanisms and folds, suggest an evolutionary link between the ATP PPases and PAPS reductases. Together with the N type ATP PPases, PAPS reductases and ATP sulphurylases are proposed to form a new family of homologous enzymes with adenine nucleotide alpha-hydrolase activity. The open, reduced form of PAPS reductase is able to bind PAPS, whereas the closed oxidized form cannot. A movement between the two monomers of the dimer may allow this switch in conformation to occur.

Structural analysis of human alpha-class glutathione transferase A1-1 in the apo-form and in complexes with ethacrynic acid and its glutathione conjugate.

BACKGROUND: Glutathione transferases (GSTs) constitute a family of isoenzymes that catalyze the conjugation of the tripeptide glutathione with a wide variety of hydrophobic compounds bearing an electrophilic functional group. Recently, a number of X-ray structures have been reported which have defined both the glutathione- and the substrate-binding sites in these enzymes. The structure of the glutathione-free enzyme from a mammalian source has not, however, been reported previously. RESULTS: We have solved structures of a human alpha-class GST, isoenzyme A1-1, both in the unliganded form and in complexes with the inhibitor ethacrynic acid and its glutathione conjugate. These structures have been refined to resolutions of 2.5 A, 2.7 A and 2.0 A respectively. Both forms of the inhibitor are clearly present in the associated electron density. CONCLUSIONS: The major differences among the three structures reported here involve the C-terminal alpha-helix, which is a characteristic of the alpha-class enzyme. This helix forms a lid over the active site when the hydrophobic substrate binding site (H-site) is occupied but it is otherwise disordered. Ethacrynic acid appears to bind in a non-productive mode in the absence of the coenzyme glutathione.

Two-dimensional crystallization and preliminary structure analysis of light harvesting II (B800-850) complex from the purple bacterium Rhodovulum sulfidophilum.

Light-harvesting complex II (B800/850) from the purple bacterium Rhodovulum (Rhv.) sulfidophilum has been isolated using a new protocol. It has been shown by analytical ultracentrifugation and native gels to be most likely an octamer. Two-dimensional crystals have been obtained by microdialysis. The plane group is p4212 with a = b = 157 A. The crystals diffract to 18 A in negative stain. Projection maps show clearly that LHII is organized in ring-like particles with an outer diameter of about 76 A.

Crystallographic refinement at 2.3 A resolution and refined model of the photosynthetic reaction centre from Rhodopseudomonas viridis.

The atomic model of the photosynthetic reaction centre from the purple bacterium Rhodopseudomonas viridis has been refined to an R-value of 0.193 at 2.3 A resolution. The refined model contains 10,288 non-hydrogen atoms; 10,045 of these have well defined electron density. A Luzzati-plot indicates an average co-ordinate error of 0.26 A. During refinement, the positions of a partially ordered carotenoid, a unibiquinone in the partially occupied QB site, a detergent molecule, seven putative sulphate ions, and 201 water molecules were found. More than half of these waters are bound at interfaces between protein subunits and therefore contribute significantly to subunit interactions. Water molecules also play important structural and probably functional roles in the environment of some of the cofactors. Two water molecules form hydrogen bonds to the accessory bacteriochlorophylls and to the protein in the vicinity of the special pair of bacteriophylls, the primary electron donor. A group of about 10 water molecules is bound near the binding site of the secondary quinone QB. These waters are likely to participate in the transfer of protons to the doubly reduced QB.

Functional significance of arginine 15 in the active site of human class alpha glutathione transferase A1-1.

Arg15 is a conserved active-site residue in class Alpha glutathione transferases. X-ray diffraction studies of human glutathione transferase A1-1 have shown that N epsilon of this amino acid residue is adjacent to the sulfur atom of a glutathione derivative bound to the active site, suggesting the presence of a hydrogen bond. The phenolic hydroxyl group of Tyr9 also forms a hydrogen bond to the sulfur atom of glutathione, and removal of this hydroxyl group causes partial inactivation of the enzyme. The present study demonstrates by use of site-directed mutagenesis the functional significance of Arg15 for catalysis. Mutation of Arg15 into Leu reduced the catalytic activity by 25-fold, whereas substitution by Lys caused only a threefold decrease, indicating the significance of a positively charged residue at position 15. Mutation of Arg15 into Ala or His caused a substantial reduction of the specific activity (200 or 400-fold, respectively), one order of magnitude more pronounced than the effect of the Tyr9-->Phe mutation. Double mutations involving residues 9 and 15 demonstrated that the effects of mutations at the two positions were additive except for the substitution of His for Arg15, which appeared to cause secondary structural effects. The pKa value of the phenolic hydroxyl of Tyr9 was determined by UV absorption difference spectroscopy and was found to be 8.1 in the wild-type enzyme. The corresponding pKa values of mutants R15K, R15H and R15L were 8.5, 8.7 and 8.8, respectively, demonstrating the contribution of the guanidinium group of Arg15 to the electrostatic field in the active site. Addition of glutathione caused an increased pKa value of Tyr9; this effect was not obtained with S-methylglutathione. These results show that Tyr9 is protonated when glutathione is bound to the enzyme at physiological pH values. The involvement of an Arg residue in the binding and activation of glutathione is a feature that distinguishes class Alpha glutathione transferases from members in other glutathione transferase classes.

Structure determination and refinement of human alpha class glutathione transferase A1-1, and a comparison with the Mu and Pi class enzymes.

The crystal structure of human alpha class glutathione transferase A1-1 has been determined and refined to a resolution of 2.6 A. There are two copies of the dimeric enzyme in the asymmetric unit. Each monomer is built from two domains. A bound inhibitor, S-benzyl-glutathione, is primarily associated with one of these domains via a network of hydrogen bonds and salt-links. In particular, the sulphur atom of the inhibitor forms a hydrogen bond to the hydroxyl group of Tyr9 and the guanido group of Arg15. The benzyl group of the inhibitor is completely buried in a hydrophobic pocket. The structure shows an overall similarity to the mu and pi class enzymes particularly in the glutathione-binding domain". The main difference concerns the extended C terminus of the alpha class enzyme which forms an extra alpha-helix that blocks one entrance to the active site and makes up part of the substrate binding site.

Crystallization and preliminary X-ray studies on the core proteins of cellobiohydrolase I and endoglucanase I from Trichoderma reesei.

The catalytic core domains of cellobiohydrolase I (CBHI) and endoglucanase I (EGI) from Trichoderma reesei have been crystallized using the hanging drop vapour diffusion method. In the case of CBHI, use of polyethylene glycol 20,000, and calcium chloride at low pH produced good quality single crystals suitable for X-ray studies. The crystals belong to a primitive orthorhombic space group with unit cell dimensions a = 84.0 A, b = 86.2 A, c = 111.8 A, and diffract beyond 2.0 A resolution. Bipyramidal crystals of EGI core were grown from ammonium sulphate at pH 7.5. The crystals are tetragonal, either P4(1)22 or the enantiomorph P4(3)22, with cell dimensions a = b = 101.8 A and c = 198.0 A, and at best diffract to a resolution of 2.5 A.

The crystal structure of the catalytic core domain of endoglucanase I from Trichoderma reesei at 3.6 A resolution, and a comparison with related enzymes.

Cellulose is the most abundant polymer in the biosphere. Although generally resistant to degradation, it may be hydrolysed by cellulolytic organisms that have evolved a variety of structurally distinct enzymes, cellobiohydrolases and endoglucanases, for this purpose. Endoglucanase I (EG I) is the major endoglucanase produced by the cellulolytic fungus Trichoderma reesei, accounting for 5 to 10% of the total amount of cellulases produced by this organism. Together with EG I from Humicola insolens and T. reesei cellobiohydrolase I (CBH I), the enzyme is classified into family 7 of the glycosyl hydrolases, and it catalyses hydrolysis with a net retention of the anomeric configuration. The structure of the catalytic core domain (residues 1 to 371) of EG I from T. reesei has been determined at 3.6 A resolution by the molecular replacement method using the structures of T. reesei CBH I and H. insolens EG I as search models. By employing the 2-fold non-crystallographic symmetry (NCS), the structure was refined successfully, despite the limited resolution. The final model has an R-factor of 0.201 (Rfree 0.258). The structure of EG I reveals an extended, open substrate-binding cleft, rather than a tunnel as found in the homologous cellobiohydrolase CBH I. This confirms the earlier proposal that the tunnel-forming loops in CBH I have been deleted in EG I, which has resulted in an open active site in EG I, enabling it to function as an endoglucanase. Comparison of the structure of EG I with several related enzymes reveals structural similarities, and differences that relate to their biological function in degrading particular substrates. A possible structural explanation of the drastically different pH profiles of T. reesei and H. insolens EG I is proposed.

Membrane association of FtsY, the E. coli SRP receptor.

FtsY, the Escherichia coli homologue of the eukaryotic SRP receptor (SR alpha), is located both in the cytoplasm and in the inner membrane of E. coli. Similar to SR alpha, FtsY consists of two major domains: a strongly acidic N-terminal domain (A) and a C-terminal GTP binding domain (NG) of which the crystal structure has recently been determined. The domains were expressed both in vivo and in vitro to examine their subcellular localization. The results suggest that both domains associate with the membrane but that the nature of the association differs.

First glance on the three-dimensional structure of the photosynthetic reaction center from a herbicide-resistant Rhodopseudomonas viridis mutant.

A first model of the three-dimensional structure of the photosynthetic reaction center of the mutant T1 (SerL223----Ala, ArgL217----His) from Rhodopseudomonas viridis, resistant toward the triazine herbicide terbutryn (2-methylthio-4-ethylamino-6-t-butylamino-s-triazine), has been developed from X-ray data measured to a resolution of 2.5 A. The secondary quinone, QB, which in T1 binds better than in the wild type, is present in the crystals. Both substituted residues are clearly visible in the difference fourier map. The replacement of these two residues in the QB site causes only minor changes in the overall structure of the protein.

Study of QB- stabilization in herbicide-resistant mutants from the purple bacterium Rhodopseudomonas viridis.

The pH dependences of the rate constants of P+QB- (kBP) and P+QA- (kAP) charge recombination decays have been studied by flash-induced absorbance change technique, in chromatophores of three herbicide-resistant mutants from Rhodopseudomonas (Rps.) viridis, and compared to the wild type. P, QA, and QB are the primary electron donor and the primary and the secondary quinone acceptors, respectively. The triazine resistant mutants T1 (Arg L217----His and Ser L223----Ala), T3 (Phe L216----Ser and Val M263----Phe), and T4 (Tyr L222----Phe), all mutated in the QB binding pocket of the reaction center, have previously been characterized (Sinning, I., Michel, H., Mathis, P., & Rutherford, A. W. (1989) Biochemistry 28, 5544-5553). The pH dependence curves of kBP in T4 and the wild type are very close. This confirms that the sensitivity toward DCMU of T4 is mainly due to a structural rearrangement in the QB pocket rather than to a change in the charge distribution in this part of the protein. In T3, a 6-fold increase of kAP is observed (kAP = 4200 +/- 300 s-1 at pH 8) compared to that of the wild type (kAP = 720 +/- 50 s-1 at pH 8). We propose that the Val M263----Phe mutation induces a free energy decrease between P+QA- and P+I- (delta G zero IA) (I is the primary electron acceptor) of about 49 meV. The very different pH dependence of kAP in T3 suggests a substantial change in the QA pocket. The 2.5 times increase of kAP above pH 9.5 in the wild type is no longer detected in T3.(ABSTRACT TRUNCATED AT 250 WORDS)

Deletion of the 6-kDa subunit affects the activity and yield of the bc1 complex from Rhodovulum sulfidophilum.

The cytochrome bc1 complex from Rhodovulum sulfidophilum purifies as a four-subunit complex: the cytochrome b, cytochrome c1 and Rieske iron-sulphur proteins, which are encoded together in the fbc operon, as well as a 6-kDa protein. The gene encoding the 6-kDa protein, named fbcS, has been identified. It is located within the sox operon, which encodes the subunits of sarcosine oxidase. The encoded 6-kDa protein is very hydrophobic and is predicted to form a single transmembrane helix. It shows no sequence homology to any known protein. The gene has been knocked-out of the genome and a three-subunit complex can be purified. This deletion leads to a large reduction in the yield of the isolated complex and in its activity compared to wild-type. The high quinone content found in the wild-type complex is, however, maintained after removal of the 6-kDa protein. Surprisingly, a fourth subunit of approximately 6 kDa is again found to copurify with the Rhv. sulfidophilum bc1 complex when only the fbc operon is expressed heterologously in a near-relative, Rhodobacter capsulatus, which lacks this small subunit in its own bc1 complex.

Expression, crystallization and preliminary X-ray diffraction study of FtsY, the docking protein of the signal recognition particle of E. coli.

FtsY is the docking protein or SR alpha homologue in E. coli. It is involved in targeting secretory proteins to the cytoplasmic membrane by interacting with the signal recognition particle, controlled by guanosine 5'-triphosphate. Two different constructs have been used in crystallization studies: the full-length protein and a truncated fragment with a his-tag at the C terminus. Only the second construct resulted in crystals suitable for x-ray diffraction. The crystals belong to the monoclinic space group P2(1) with cell dimensions a = 32.20 A, b = 79.57 A, c = 59.21 A, and beta = 94.45, and contain one molecule per asymmetric unit. At cryogenic temperatures the crystals diffract to a resolution limit of 2.5 A by using a rotating anode, and beyond 1.8 A by using synchrotron radiation.

Crystal structure of the NG domain from the signal-recognition particle receptor FtsY.

Newly synthesized proteins destined either for secretion or incorporation into membranes are targeted to the membrane translocation machinery by a ubiquitous system consisting of a signal-recognition particle (SRP) and its receptor. Both the SRP receptor and the protein within the SRP that binds the signal sequence contain GTPases. These two proteins, together with the RNA component of the SRP, form a complex and thereby regulate each other's GTPase activity. Here we report the structure of the GTPase-containing portion of FtsY, the functional homologue of the SRP receptor of Escherichia coli, at 2.2 A resolution without bound nucleotide. This so-called NG domain displays similarities to the Ras-related GTPases, as well as features unique to the SRP-type GTPases, such as a separate amino-terminal domain, an insertion within the p21ras (Ras) effector domain, and a wide-open GTP-binding region. The structure explains the low affinity of FtsY for GTP, and suggests rearrangements that may occur on nucleotide binding. It also identifies regions potentially involved in the transmission of signals between domains and in interactions with regulatory proteins.

The signal recognition particle receptor of Escherichia coli (FtsY) has a nucleotide exchange factor built into the GTPase domain.

Targeting of many secretory and membrane proteins to the inner membrane in Escherichia coli is achieved by the signal recognition particle (SRP) and its receptor (FtsY). In E. coli SRP consists of only one polypeptide (Ffh), and a 4.5S RNA. Ffh and FtsY each contain a conserved GTPase domain (G domain) with an alpha-helical domain on its N terminus (N domain). The nucleotide binding kinetics of the NG domain of the SRP receptor FtsY have been investigated, using different fluorescence techniques. Methods to describe the reaction kinetically are presented. The kinetics of interaction of FtsY with guanine nucleotides are quantitatively different from those of other GTPases. The intrinsic guanine nucleotide dissociation rates of FtsY are about 10(5) times higher than in Ras, but similar to those seen in GTPases in the presence of an exchange factor. Therefore, the data presented here show that the NG domain of FtsY resembles a GTPase-nucleotide exchange factor complex not only in its structure but also kinetically. The I-box, an insertion present in all SRP-type GTPases, is likely to act as an intrinsic exchange factor. From this we conclude that the details of the GTPase cycle of FtsY and presumably other SRP-type GTPases are fundamentally different from those of other GTPases.

Characterization of four herbicide-resistant mutants of Rhodopseudomonas viridis by genetic analysis, electron paramagnetic resonance, and optical spectroscopy.

Herbicides of the triazine class block electron transfer in the photosynthetic reaction centers of purple bacteria and PSII of higher plants. They are thought to act by competing with one of the electron acceptors, the secondary quinone, QB, for its binding site. Several mutants of the purple bacterium Rhodopseudomonas viridis resistant to terbutryn [2-(methylthio)-4-(ethylamino)-6-(tert-butylamino)-s-triazine] have been isolated by their ability to grow photosynthetically in the presence of the herbicide. Sequence analysis of the genes coding for the L and M subunits of the reaction center showed that four different mutants were obtained, two of them being double mutated: T1 (SerL223----Ala and ArgL217----His), T3 (PheL216----Ser and ValM263----Phe), T4 (TyrL222----Phe), and T6 (PheL216----Ser). The residues L223 and L216 are involved in binding of QB, whereas L217 and L222 are not. M263 is part of the binding pocket of the primary quinone, QA. The affinity of the reaction centers for terbutryn and the electron transfer inhibitor o-phenanthroline, determined via the biphasic charge recombination after one flash, is decreased for all mutants. The affinity for ubiquinone 9 is also decreased, except in T1. Characterization by EPR spectroscopy showed that the QB.-Fe2+ signal of T4, having a g = 1.93 peak, is different from the signals obtained with the wild type and the other mutants but very similar to those of Rhodospirillum rubrum and PSII. The results obtained by the combination of these different techniques are discussed with respect to the three-dimensional structure of the wild type and the mode of binding of ubiquinone, terbutryn, and o-phenanthroline as determined by X-ray structure analysis.