X-ray crystal structure of arrestin from bovine rod outer segments.

Retinal arrestin is the essential protein for the termination of the light response in vertebrate rod outer segments. It plays an important role in quenching the light-induced enzyme cascade by its ability to bind to phosphorylated light-activated rhodopsin (P-Rh*). Arrestins are found in various G-protein-coupled amplification cascades. Here we report on the three-dimensional structure of bovine arrestin (relative molecular mass, 45,300) at 3.3 A resolution. The crystal structure comprises two domains of antiparallel beta-sheets connected through a hinge region and one short alpha-helix on the back of the amino-terminal fold. The binding region for phosphorylated light-activated rhodopsin is located at the N-terminal domain, as indicated by the docking of the photoreceptor to the three-dimensional structure of arrestin. This agrees with the interpretation of binding studies on partially digested and mutated arrestin.

Crystallization and preliminary X-ray analysis of arrestin from bovine rod outer segment.

We present the first X-ray study of a member of the arrestin family, the bovine retinal arrestin. Arrestin is essential for the fine regulation and termination of the light-induced enzyme cascade in vertebrate rod outer segments. It plays an important role in quenching phototransduction by its ability to preferentially bind to phosphorylated light-activated rhodopsin. The crystals diffract between 3 angstroms and 3.5 angstroms (space group P2(1)2(1)2, cell dimensions a = 169.17 angstroms, b = 185.53 angstroms, c = 90.93 angstroms, T = 100 K). The asymmetric unit contains four molecules with a solvent content of 68.5% by volume.

X-ray crystallographic and calorimetric studies of the effects of the mutation Trp59-->Tyr in ribonuclease T1.

Two mutants of ribonuclease T1 (RNaseT1), [59-tyrosine]ribonuclease T1 (W59Y) and [45-tryptophan,59-tyrosine]ribonuclease T1 (Y45W/W59Y) possess between 150% and 190% wild-type activity. They have been crystallised as complexes of the inhibitor 2'-guanylic acid and analysed by X-ray diffraction at resolutions of 0.23 nm and 0.24 nm, respectively. The space group for both is monoclinic, P2(1), with two molecules/asymmetric unit, W59Y: a = 4.934 nm, b = 4.820 nm, c = 4.025 nm, beta = 90.29 degrees. Y45W/W59Y: a = 4.915 nm, b = 4.815 nm, c = 4.015 nm, beta = 90.35 degrees. Compared to wild-type RNaseT1 in complex with 2'-guanylic acid (2'GMP) both mutant inhibitor complexes indicate that the replacement of Trp59 by Tyr leads to a 0.04-nm inward shift of the single alpha-helix and to significant differences in the active-site geometry, inhibitor conformation and inhibitor binding. Calorimetric studies of a range of mutants [24-tryptophan]ribonuclease T1 (Y24W), [42-tryptophan]ribonuclease T1 (Y42W), [45-tryptophan]ribonuclease T1 (Y45W), [92-alanine]ribonuclease T1 (H92A) and [92-threonine]ribonuclease T1 (H92T) with and without the further mutation Trp59-->Tyr showed that mutant proteins for which Trp59 is replaced by Tyr exhibit slightly decreased thermal stability.

Crystallographic study of Glu58Ala RNase T1 x 2'-guanosine monophosphate at 1.9-A resolution.

Glu58 is known to participate in phosphodiester transesterification catalyzed by the enzyme RNase T1. For Glu58 RNase T1, an altered mechanism has been proposed in which His40 replaces Glu58 as the base catalyst [Steyaert, J., Hallenga, K., Wyns, L., & Stanssens, P. (1990) Biochemistry 29, 9064-9072]. Glu58Ala Rnase T1 has been cocrystallized with guanosine 2'-monophosphate (2'-GMP). The crystals are of space group P2(1), with one molecule per asymmetric unit (a = 32.44 A, b = 49.64 A, c = 26.09 A, beta = 99.17 degrees). The three-dimensional structure of the enzyme was determined to a nominal resolution of 1.9 A, yielding a crystallographic R factor of 0.178 for all X-ray data. Comparison of this structure with wild-type structures leads to the following conclusions. The minor changes apparent in the tertiary structure can be explained by either the mutation of Glu58 or by the change in the space group. In the active site, the extra space available through the mutation of Glu58 is occupied by the phosphate group (after a reorientation) and by a solvent molecule replacing a carboxylate oxygen of Glu58. This solvent molecule is a candidate for participation in the altered mechanism of this mutant enzyme. Following up on a study of conserved water sites in RNase T1 crystallized in space group P2(1)2(1)2(1) [Malin, R., Zielenkiewicz, P., & Saenger, W. (1991) J. Mol. Biol. 266, 4848-4852], we investigated the hydration structure for four different packing modes of RNase T1.(ABSTRACT TRUNCATED AT 250 WORDS)

The complex between ribonuclease T1 and 3'GMP suggests geometry of enzymic reaction path. An X-ray study.

The crystal structure of the complex between ribonuclease T1 and 3'GMP suggests that (a) a substrate GpN is bound to the active site of ribonuclease T1 in a conformation that actively supports the catalytic process, (b) the reaction occurs in an in-line process, (c) His40 N epsilon H+ activates O2'-H, (d) Glu58 carboxylate acts as base and His92 N epsilon H+ as acid in a general acid-base catalysis. The crystals have the monoclinic space group P2(1), a = 4.968 nm, b = 4.833 nm, c = 4.048 nm, beta = 90.62 degrees with two molecules in the asymmetric unit. The structure was determined by molecular replacement and refined to R = 15.3% with 11,338 data > or = 1 sigma (Fo) in the resolution range 1.0-0.2 nm; this includes 180 water molecules and two Ca2+. The structure of ribonuclease T1 is as previously observed. 3'GMP is bound in syn conformation; guanine is located in the specific recognition site, the ribose adopts C4'-exo puckering, the ribose phosphate is extended with torsion angle epsilon in trans. The O2'-H group is activated by accepting and donating hydrogen bonds from His40 N epsilon H+ and to Glu58 O epsilon 1; the phosphate is hydrogen bonded to Glu58 O epsilon 2H, Arg77 N epsilon H+ and N eta 2H+, Tyr38 O eta H, His92 N eta H+. The conformation of ribose phosphate is such that O2' is at a distance of 0.31 nm from phosphorus, and opposite the P-OP3 bond which accepts a hydrogen bond from His92 N epsilon H+; we infer from a model building study that this bond is equivalent to the scissile P-O5' in a substrate GpN.

Three-dimensional structure of the ternary complex between ribonuclease T1, guanosine 3',5'-bisphosphate and inorganic phosphate at 0.19 nm resolution.

The ternary complex formed between RNase T1, guanosine 3',5'-bisphosphate (3',5'-pGp) and Pi crystallizes in the cubic space group I23 with a = 8.706(1) nm. In a previous publication [Lenz, A., Heinemann, U., Maslowska, M. & Saenger, W. (1991) Acta Crystallogr. B47, 521-527], the structure of the complex (in which Pi was not located) was described at a resolution of 0.32 nm. This is now extended to 0.19 nm with newly grown, larger crystals. Refinement with restrained least-squares converged at R = 17.8% for 8027 reflections with [Fo[ > or = 1 sigma ([Fo[); the final model comprises 120 water molecules. 3',5'-pGp is bound to RNase T1 in the anti form, with guanine in the specific recognition site; the 3'-phosphate protrudes into the solvent, and the 5'-phosphate hydrogen bonds with Lys41 O and Asn43 N4. A tetrahedral anion assigned as Pi occupies the catalytic site and hydrogen bonds to the side chains of Tyr38, Glu58, Arg77 and His92. The overall polypeptide fold of RNase T1 in the cubic space group does not differ significantly from that in the orthorhombic space group P2(1)2(1)2(1) except for changes < or = 0.2 nm in loop regions 69-72 and 95-98.

Role of histidine-40 in ribonuclease T1 catalysis: three-dimensionalstructures of the partially active His40Lys mutant.

Histidine-40 is known to participate in phosphodiester transesterification catalyzed by the enzyme ribonuclease T1. A mutant enzyme with a lysine replacing the histidine-40 (His40Lys RNase T1) retains considerable catalytic activity [Steyaert, J., Hallenga, K., Wyns, L., & Stanssens, P. (1990) Biochemistry 29, 9064-9072]. We report on the crystal structures of His40Lys RNase T1 containing a phosphate anion and a guanosine 2'-phosphate inhibitor in the active site, respectively. Similar to previously described structures, the phosphate-containing crystals are of space group P2(1)2(1)2(1), with one molecule per asymmetric unit (a = 48.27 A, b = 46.50 A, c = 41.14 A). The complex with 2'-GMP crystallized in the lower symmetry space group P2(1), with two molecules per asymmetric unit (a = 49.20 A, b = 48.19 A, c = 40.16 A, beta = 90.26). The crystal structures have been solved at 1.8- and 2.0-A resolution yielding R values of 14.5% and 16.0%, respectively. Comparison of these His40Lys structures with the corresponding wild-type structures, containing 2'-GMP [Arni, R., Heinemann, U., Tokuoka, R., & Saenger, W. (1988) J. Biol. Chem. 263, 15358-15368] and vanadate [Kostrewa, D., Hui-Woog Choe, Heinemann, U., & Saenger, W. (1989) Biochemistry 28, 7692-7600] in the active site, respectively, leads to the following conclusions. First, the His40Lys mutation causes no significant changes in the overall structure of RNase T1; second, the Lys40 side chains in the mutant structures occupy roughly the same space as His40 in the corresponding wild-type RNase T1 structures.(ABSTRACT TRUNCATED AT 250 WORDS)

Crystal structure of the factor for inversion stimulation FIS at 2.0 A resolution.

The factor for inversion stimulation (FIS) binds as a homodimeric molecule to a loose 15 nucleotide consensus sequence in DNA. It stimulates DNA-related processes, such as DNA inversion and excision, it activates transcription of tRNA and rRNA genes and it regulates its own synthesis. FIS crystallizes as a homodimer, with 2 x 98 amino acid residues in the asymmetric unit. The crystal structure was determined with multiple isomorphous replacement and refined to an R-factor of 19.2% against all the 12,719 X-ray data (no sigma-cutoff) extending to 2.0 A resolution. The two monomers are related by a non-crystallographic dyad axis. The structure of the dimer is modular, with the first 23 amino acid residues in molecule M1 and the first 24 in molecule M2 disordered and not "seen" in the electron density. The polypeptide folds into four alpha-helices, with alpha A, alpha A' (amino acid residues 26 to 40) and alpha B, alpha B' (49 to 69) forming the core of the FIS dimer, which is stabilized by hydrophobic forces. To the core are attached "classical" helix-turn-helix motifs, alpha C, alpha D (73 to 81 and 84 to 94) and alpha C', alpha D'. The connections linking the helices are structured by two beta-turns for alpha A/alpha B, and alpha C1 type extensions are observed at the C termini of helices alpha B, alpha C and alpha D. Helices alpha D and alpha D' contain 2 x 6 positive charges; they are separated by 24 A and can bind adjacent major grooves in B-type DNA if it is bent 90 degrees. The modular structure of FIS is also reflected by mutation experiments; mutations in the N-terminal part and alpha A interfere with FIS binding to invertases, and mutations in the helix-turn-helix motif interfere with DNA binding.

Structure of ribonuclease T1 complexed with zinc(II) at 1.8 A resolution: a Zn2+.6H2O.carboxylate clathrate.

In order to study the inhibitory effect of Zn2+ on ribonuclease T1 [RNase T1; Itaya & Inoue (1982). Biochem. J. 207, 357-362], the enzyme was cocrystallized with 2 mM Zn2+, pH 5.2, from a solution containing 55% (v/v) 2-methyl-2,4-pentanediol. The crystals are orthorhombic, P2(1)2(1)2(1), a = 48.71 (1), b = 46.51 (1), c = 41.14 (1) A, Z = 4, V = 93203 A3. The crystal structure was determined by molecular replacement and refined by restrained least-squares methods based on Fhkl for 8291 unique reflections with Fo greater than or equal to 1 sigma (Fo) in the resolution range 10 to 1.8 A and converged at a crystallographic R factor of 0.140. The Zn2+ is not bonded to the active site of RNase T1, probably because the His40 and His92 side chains are protonated. Zn2+ occupies the same site as Ca2+ in a series of crystal structures of free and nucleotide-complexed RNase T1. It is coordinated to Asp15 carboxylate and to six water molecules forming a dodecahedron of square antiprismatic form. The Zn2+...O distances are approximately 2.5 A, suggesting that Zn2+ is clathrated and not coordinated, which would require distances of 2.0 A.

His92Ala mutation in ribonuclease T1 induces segmental flexibility. An X-ray study.

In the genetically mutated ribonuclease T1 His92Ala (RNase T1 His92Ala), deletion of the active site His92 imidazole leads to an inactive enzyme. Attempts to crystallize RNase T1 His92Ala under conditions used for wild-type enzyme failed, and a modified protocol produced two crystal forms, one obtained with polyethylene glycol (PEG), and the other with phosphate as precipitants. Space groups are identical to wild-type RNase T1, P2(1)2(1)2(1), but unit cell dimensions differ significantly, associated with different molecular packings in the crystals; they are a = 31.04 A, b = 62.31 A, c = 43.70 A for PEG-derived crystals and a = 32.76 A, b = 55.13 A, c = 43.29 A for phosphate-derived crystals, compared to a = 48.73 A, b = 46.39 A, c = 41.10 A for uncomplexed wild-type RNase T1. The crystal structures were solved by molecular replacement and refined by stereochemically restrained least-squares methods based on Fo greater than or equal to sigma (Fo) of 3712 reflections in the resolution range 10 to 2.2 A (R = 15.8%) for the PEG-derived crystal and based on Fo greater than or equal to sigma (Fo) of 6258 reflections in the resolution range 10 to 1.8 A (R = 14.8%) for the phosphate-derived crystal. The His92Ala mutation deletes the hydrogen bond His92N epsilon H ... O Asn99 of wild-type RNase T1, thereby inducing structural flexibility and conformational changes in the loop 91 to 101 which is located at the periphery of the globular enzyme. This loop is stabilized in the wild-type protein by two beta-turns of which only one is retained in the crystals obtained with PEG. In the crystals grown with phosphate as precipitant, both beta-turns are deleted and the segment Gly94-Ala95-Ser96-Gly97 is so disordered that it is not seen at all. In addition, the geometry of the guanine binding site in both mutant studies is different from "empty" wild-type RNase T1 but similar to that found in complexes with guanosine derivatives: the Glu46 side-chain carboxylate hydrogen bonds to Tyr42 O eta; water molecules that are present in the guanine binding site of "empty" wild-type RNase T1 are displaced; the Asn43-Asn44 peptide is flipped such that phi/psi-angles of Asn44 are in alpha L-conformation (that is observed in wild-type enzyme when guanine is bound).(ABSTRACT TRUNCATED AT 400 WORDS)

Ribonuclease T1 with free recognition and catalytic site: crystal structure analysis at 1.5 A resolution.

The free form of ribonuclease T1 (RNase T1) has been crystallized at neutral pH, and the three-dimensional structure of the enzyme has been determined at 1.5 A nominal resolution. Restrained least-squares refinement yielded an R value of 14.3% for 12,623 structure amplitudes. The high resolution of the structure analysis permits a detailed description of the solvent structure around RNase T1, the reliable rotational setting of several side-chain amide and imidazole groups and the identification of seven disordered residues. Among these, the disordered and completely internal Val78 residue is noteworthy. In the RNase T1 crystal structures determined thus far it is always disordered in the absence of bound guanosine, but not in its presence. A systematic analysis of hydrogen bonding reveals the presence in RNase T1 of 40 three-center and an additional seven four-center hydrogen bonds. Three-center hydrogen bonds occur predominantly in the alpha-helix, where their minor components close 3(10)-type turns, and in beta-sheets, where their minor components connect the peptide nitrogen and carbonyl functions of the same residue. The structure of the free form is compared with complexes of RNase T1 with filled base recognition site and/or catalytic site. Several structural rearrangements occurring upon inhibitor or substrate binding are clearly apparent. In conjunction with the available biochemical knowledge, they are used to describe probable steps occurring early during RNase T1-catalyzed phosphate transesterification.

Three-dimensional structure of the E. coli DNA-binding protein FIS.

The factor for inversion stimulation, FIS, is involved in several cellular processes, including site-specific recombination and transcriptional activation. In the reactions catalysed by the DNA invertases Gin, Hin and Cin, FIS stimulates recombination by binding to an enhancer sequence. Within the enhancer, two FIS dimers (each 2 x 98 amino acids) bind to two 15-base-pair consensus sequences and induce bending of the DNA. Current models propose that the enhancer-FIS complex organizes a specific synapse, either through direct interactions with Gin, or by modelling the substrate into a configuration suitable for recombination. Using X-ray analysis at 2.0 A resolution, we now show that FIS is composed of four alpha helices tightly intertwined to form a globular dimer with two protruding helix-turn-helix motifs. The 24 N-terminal amino acids are so poorly defined in the electron density map as to make interpretation doubtful, indicating that they might act as 'feelers' suitable for DNA or protein (invertase) recognition. We infer from model building that DNA has to bend for tight binding to FIS.

Crystal structure of guanosine-free ribonuclease T1, complexed with vanadate (V), suggests conformational change upon substrate binding.

Ribonuclease T1 was crystallized in the presence of vanadate(V). The crystal structure was solved by molecular replacement and refined by least-squares methods using stereochemical restraints. The refinement was based on data between 10 and 1.8 A and converged at a crystallographic R factor of 0.137. Except for the substrate-recognition site the three-dimensional structure of ribonuclease T1 closely resembles the structure of the enzyme complexed with guanosine 2'-phosphate and its derivatives. A tetrahedral anion was found at the catalytic site and identified as H2VO4-. This is the first crystal structure of ribonuclease T1 determined in the absence of bound substrate analogue. Distinct structural differences between guanosine-free and complexed ribonuclease T1 are observed at the base-recognition site: The side chains of Tyr45 and Glu46 and the region around Asn98 changed their conformations, and the peptide bond between Asn43 and Asn44 has turned around by 140 degrees. We suggest that the structural differences seen in the crystal structures of free and complexed ribonuclease T1 are related to conformational adjustments associated with the substrate binding process.

Crystallization of the DNA-binding Escherichia coli protein FIS.

The specific DNA-binding protein FIS (factor for inversion stimulation), which stimulates site-specific DNA inversion by interaction with an enhancer sequence, was purified from an Escherichia coli strain overproducing the protein. FIS was crystallized at room temperature by microdialysis against 1.2 to 1.5 M-sodium/potassium phosphate containing 10 mM-Tris.HCl, 0.5 to 1 M-NaCl and 1 mM-NaN3 at pH 8.0 to 8.2. The crystals are stout prisms and suitable for X-ray diffraction study beyond 2.5 A resolution. They belong to the orthorhombic space group P2(1)2(1)2(1). The unit cell has dimensions a = 47.57(4) A, b = 51.13(4) A, c = 79.83(6) A and contains one FIS dimer in the asymmetric unit.

Comparative studies of ribulose-1,5-biphosphate carboxylase/oxygenase from Alcaligenes eutrophus H16 cells, in the active and CABP-inhibited forms.

RuBisCO (D-ribulose-1,5-biphosphate carboxylase/oxygenase; EC 4.1.1.39) has been isolated from the autotrophic hydrogen-oxidizing bacterium Alcaligenes eutrophus H16. Combining photon correlation and sedimentation analysis transport parameters of the enzyme were investigated in the active, (E.CO2.Mg2+) as a ternary complex, and inactive state, (E.CO2.Mg2+.CABP) as a quaternary complex, where RuBisCO is complexed with the transition state analogue CABP (2-C-carboxy-D-arabinitol-1,5-biphosphate). Within experimental error, no difference has been detected between the diffusion and sedimentation coefficients (D020,w = 2.72(+/- 0.07) x 10(-7) cm2 s-1, s020,w = 17.8(+/- 0.5)S) of active and CABP-complexed enzyme thus leading to the conclusion that the molecule, at least in solution, does not assume a different conformation when complexed with CABP.

Crystallization of the activated ternary complex of ribulose-1,5-bisphosphate carboxylase-oxygenase isolated from Rhodospirillum rubrum and from an Escherichia coli clone.

Ribulose-1,5-bisphosphate carboxylase-oxygenase was purified from the photosynthetic bacterium Rhodospirillum rubrum as well as from an Escherichia coli clone overproducing the enzyme. Although the latter enzyme contains 25 additional amino acid residues at the N terminus, both preparations yielded isomorphous tetragonal, bipyramidal crystals of the ternary complex of the enzyme with CO2 and Mg2+. Crystallization is sensitive to variation in pH and to the addition of the transition state analog, 2-carboxyarabinitol-1,5-bisphosphate. The systematic absences in the X-ray diffraction photographs suggest a tetragonal space group P4(3)2(1)2 or the enantiomorph P4(1)2(1)2 with cell dimensions a = b = 83 A, c = 290 A. There is one molecule per asymmetric unit. The resolution on still photographs is 3 A. The crystals are comparable to some of those already published but differ from others.