Atomic resolution structure of Escherichia coli dUTPase determined ab initio.

Cryocooled crystals of a mercury complex of Escherichia coli dUTPase diffract to atomic resolution. Data to 1.05 A resolution were collected from a derivative crystal and the structure model was derived from a Fourier map with phases calculated from the coordinates of the Hg atom (one site per subunit of the trimeric enzyme) using the program ARP/wARP. After refinement with anisotropic temperature factors a highly accurate model of the bacterial dUTPase was obtained. Data to 1.45 A from a native crystal were also collected and the 100 K structures were compared. Inspection of the refined models reveals that a large part of the dUTPase remains rather mobile upon freezing, with 14% of the main chain being totally disordered and with numerous side chains containing disordered atoms in multiple discrete conformations. A large number of those residues surround the active-site cavity. Two glycerol molecules (the cryosolvent) occupy the deoxyribose-binding site. Comparison between the native enzyme and the mercury complex shows that the active site is not adversely affected by the binding of mercury. An unexpected effect seems to be a stabilization of the crystal lattice by means of long-range interactions, making derivatization a potentially useful tool for further studies of inhibitor-substrate-analogue complexes of this protein at very high resolution.

On the enzymatic activation of NADH.

Atomic (1 A) resolution x-ray structures of horse liver alcohol dehydrogenase in complex with NADH revealed the formation of an adduct in the active site between a metal-bound water and NADH. Furthermore, a pronounced distortion of the pyridine ring of NADH was observed. A series of quantum chemical calculations on the water-nicotinamide adduct showed that the puckering of the pyridine ring in the crystal structures can only be reproduced when the water is considered a hydroxide ion. These observations provide fundamental insight into the enzymatic activation of NADH for hydride transfer.

Homotrimeric dUTPases; structural solutions for specific recognition and hydrolysis of dUTP.

Prevention of incorporation of dUTP into DNA is essential for maintenance of the genetic information. Prompt and specific removal of dUTP from the nucleotide pool, as expedited by the ubiquitous enzyme dUTPase, is therefore required for full viability in most biological systems. Conserved structural features perpetuate specificity in choice of substrate, which is crucial as hydrolysis of the structurally closely related nucleotides dTTP, dCTP and UTP would debilitate DNA and RNA synthesis. The most common family of dUTPases is the homotrimeric variety where X-ray structures are available for one bacterial, one mammalian and two retroviral dUTPases. These four enzymes have similar overall structural layouts, but the interactions that stabilise the trimer vary markedly, ranging from exclusively hydrophobic to water-mediated interactions. Trimeric dUTPases contain five conserved sequence motifs, positioned at the subunit interfaces where they contribute to the formation of the active sites. Each of the three identical active sites per trimer is built of residues contributed by all three subunits. One subunit provides residues involved in base and sugar recognition, where a beta-hairpin acts to maintain exquisite selectivity, while a second subunit contributes residues for phosphate interactions. The third subunit supplies a glycine-rich consensus motif located in the flexible C-terminal part of the subunit, known from crystallographic studies to cover the active site in the presence of substrate and certain substrate analogues. All dUTPases studied require the presence of a divalent metal ion, preferably Mg(2+), for optimal activity. The putative position of the essential metal ion has been identified in the structure of one retroviral dUTPase. Structure-function studies are essential if the properties of dUTPases are to be understood fully in relation to their biological role. In this review the structural arrangement of the homotrimeric dUTPases is discussed in the context of active site geometry, achievement of specificity and subunit interactions.

Structural basis for substrate specificity differences of horse liver alcohol dehydrogenase isozymes.

A structure determination in combination with a kinetic study of the steroid converting isozyme of horse liver alcohol dehydrogenase, SS-ADH, is presented. Kinetic parameters for the substrates, 5beta-androstane-3beta,17beta-ol, 5beta-androstane-17beta-ol-3-one, ethanol, and various secondary alcohols and the corresponding ketones are compared for the SS- and EE-isozymes which differ by nine amino acid substitutions and one deletion. Differences in substrate specificity and stereoselectivity are explained on the basis of individual kinetic rate constants for the underlying ordered bi-bi mechanism. SS-ADH was crystallized in complex with 3alpha,7alpha,12alpha-trihydroxy-5beta-cholan -24-acid (cholic acid) and NAD(+), but microspectrophotometric analysis of single crystals proved it to be a mixed complex containing 60-70% NAD(+) and 30-40% NADH. The crystals belong to the space group P2(1) with cell dimensions a = 55.0 A, b = 73.2 A, c = 92.5 A, and beta = 102.5 degrees. A 98% complete data set to 1.54-A resolution was collected at 100 K using synchrotron radiation. The structure was solved by the molecular replacement method utilizing EE-ADH as the search model. The major structural difference between the isozymes is a widening of the substrate channel. The largest shifts in C(alpha) carbon positions (about 5 A) are observed in the loop region, in which a deletion of Asp115 is found in the SS isozyme. SS-ADH easily accommodates cholic acid, whereas steroid substrates of similar bulkiness would not fit into the EE-ADH substrate site. In the ternary complex with NAD(+)/NADH, we find that the carboxyl group of cholic acid ligates to the active site zinc ion, which probably contributes to the strong binding in the ternary NAD(+) complex.

Crystallization and preliminary X-ray diffraction of Trypanosoma cruzi dUTPase.

Crystals of Trypanosoma cruzi dUTPase have been grown. Two different morphologies are observed, depending on the molecular weight of the PEG used as precipitating agent in the mother liquor, both having a hexagonal unit cell with similar dimensions. Complete X-ray diffraction data have been collected to low resolution for one of the forms. The space group is P6322, with unit-cell dimensions a = 134.15, c = 147.05 A. Peaks in the self-rotation function and the solvent content are consistent with two molecules of dUTPase per asymmetric unit.

Crystal structure of dUTPase from equine infectious anaemia virus; active site metal binding in a substrate analogue complex.

The X-ray structures of dUTPase from equine infectious anaemia virus (EIAV) in unliganded and complexed forms have been determined to 1.9 and 2.0 A resolution, respectively. The structures were solved by molecular replacement using Escherichia coli dUTPase as search model. The exploitation of a relatively novel refinement approach for the initial model, combining maximum likelihood refinement with stereochemically unrestrained updating of the model, proved to be of crucial importance and should be of general relevance.EIAV dUTPase is a homotrimer where each subunit folds into a twisted antiparallel beta-barrel with the N and C-terminal portions interacting with adjacent subunits. The C-terminal 14 and 17 amino acid residues are disordered in the crystal structure of the unliganded and complexed enzyme, respectively. Interactions along the 3-fold axis include a water-containing volume (size 207 A3) which has no contact with bulk solvent. It has earlier been shown that a divalent metal ion is essential for catalysis. For the first time, a putative binding site for such a metal ion, in this case Sr2+, is established. The positions of the inhibitor (the non-hydrolysable substrate analogue dUDP) and the metal ion in the complex are consistent with the location of the active centre established for trimeric dUTPase structures, in which subunit interfaces form three surface clefts lined with evolutionary conserved residues. However, a detailed comparison of the active sites of the EIAV and E. coli enzymes reveals some structural differences. The viral enzyme undergoes a small conformational change in the uracil-binding beta-hairpin structure upon dUDP binding not observed in the other known dUTPase structures.

The refined structure of dUTPase from Escherichia coli.

Deoxyuridine 5'-triphosphate nucleotidohydrolase (dUTPase, E.C. 3.6. 1.23) catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate and is involved in nucleotide metabolism and DNA synthesis. A crystal of the recombinant E. coli enzyme, precipitated from polyethylene glycol mixtures in the presence of succinate at pH 4.2, was used to collect synchrotron diffraction data to 1.9 A resolution, in space group R3, a = b = 86.62, c = 62.23 A. Mercury and platinum derivative data were collected at wavelengths to optimize the anomalous contribution. The resulting 2.2 A MIRAS phases differed from the final set by 40 degrees on average and produced an excellent map which was easy to interpret. The model contains 132 water molecules and refined to an R value of 13.7%. 136 residues have clear electron density out of 152 expected from the gene sequence. The 16 C-terminal residues are presumably disordered in the crystal lattice. The monomer is a 'jelly-roll' type, containing mostly beta-sheet and only one short helix. The molecule is a tight trimer. A long C-terminal arm extends from one subunit and encompasses the next one within the trimer contributing to its beta-sheet. Conserved sequence motifs common among dUTPases, previously suggested to compose the active site and confirmed in a recent study of the dUDP complex, are located at subunit-subunit interfaces along the threefold axis, in parts of the beta-sheet and in loop regions. A similar molecular architecture has recently been found in two other trimeric dUTPases.

Electrostatic effects in the kinetics of coenzyme binding to isozymes of alcohol dehydrogenase from horse liver.

The kinetic mechanism for the binding of NAD+ and NADH to the EE and SS isozymes of alcohol dehydrogenase (LADH) was studied between pH 7 and pH 10 by monitoring the quenching of tryptophan fluorescence. A consistent interpretation of all data was only possible by introducing a two-step binding mechanism. The first binding step is related to docking of the adenosine part of the coenzymes and the subsequent isomerization to the binding of the nicotinamide part. At high NADH concentrations an additional slow isomerization was identified as a conformational transition of the protein. A pH dependence for NADH binding is observed which is restricted to changes in the binding kinetics of the adenosine moiety going from pH 7 to pH 10, a tendency which is similar also for NAD+. This is attributed to pH-dependent variations in electrostatic attractions acting as a steering force of the docking process. The nicotinamide docking of NADH is equally fast for both isozymes and pH-independent over the measured range, whereas this docking equilibrium for NAD+ is pH-dependent for EE- and SS-LADH alike and the rate of association comparable. Presumably, a GluEE-366-LysSS substitution results in a stronger binding and faster association of both oxidized and reduced cofactor to the SS isozyme. A structural proof is presented for coenzyme-competitive binding of a sulfate ion, resulting in electrostatic shielding.

The protein conformation of Cd-substituted horse liver alcohol dehydrogenase and its metal-site coordination geometry in binary and ternary inhibitor complexes.

The coordination geometry of the metal at the active site in Cd-substituted horse liver alcohol dehydrogenase (LADH) has been investigated for the binary complexes of LADH with imidazole, isobutyramide, decanoic acid and Cl-, and for the ternary complexes of LADH with NADH and imidazole, NADH and isobutyramide, NAD+ and decanoic acid and NAD+ and Cl-, by using the method of perturbed angular correlation of gamma-rays (PAC). The spectral results are consistent with a flexible structure around the metal for the binary complexes with inhibitors. For ternary complexes, however, a rigid structure is observed. An exception is the ternary complex between LADH, NADH and imidazole, in which the metal site is still flexible. Comparing with available structures determined by X-ray crystallography, we found a correlation between open structures and flexible metal sites, and between closed structures and rigid metal sites. This indicates that the PAC technique can be applied to distinguish the two conformations in solution. The spectral parameters, omega(o) and eta, of the experiments, except for the complexes with imidazole, fall into two groups: one with low omega(o) and one with high omega(o) (eta is relatively constant in all experiments). In this work it is clarified that the low omega(o) values are connected with the presence of a negatively charged solvent ligand. Using an angular-overlap approach to interpret the results, the low omega(o) values are found to be compatible with a coordination geometry where the S-Cd-S (Cys174 and Cys46 coordinate to the metal) angle is about 110 degrees as suggested in [Hemmingsen, L., Bauer, R., Danielsen, E., Bjerrum. M. J., Zeppezauer, M., Adolph, H. W., Formicka, G. & Cedergren-Zeppezauer, E. (1995) Biochemistry 34, 7145-7153], whereas high omega(o) values are compatible with an S-Cd-S angle of 130 degrees. The presence of a negatively charged metal ligand, therefore, might trigger the movement of the sulfur of Cys174. As it is believed that alcohols coordinate to the metal as alcoholate ions this could be important for catalysis.

Refined structure of Cu-substituted alcohol dehydrogenase at 2.1 A resolution.

Liver alcohol dehydrogenase (LADH) is a Zn(II)-dependent dimeric enzyme. LADH with the active-site Zn(II) substituted by Cu(II) resembles blue (type I) copper proteins by its spectroscopic characteristics. In this work we present the X-ray structure of the active site Cu(II)-substituted LADH complex with NADH and dimethyl sulfoxide (DMSO). The structure was solved by molecular replacement. The space group is P2(1) with cell dimensions a = 44.4, b = 180.6, c = 50.8 A and beta = 108 degrees. There is one dimer of the enzyme in the asymmetric unit. The refinement was carried out to a crystallographic R-factor of 16.1% for 41 119 unique reflections in the resolution range 12.0 to 2.1 A. The coordination geometry of Cu(II) in LADH is compared with the active-site metal coordination in the Zn-LADH-NADH-DMSO complex and blue-copper proteins. The distances from the metal to the protein ligands (Cys46, His67 and Cys174) are similar for the Zn(II) and Cu(II) ions. The distances of the O atom of the inhibitor DMSO to the Cu(II) ion in the two subunits of the dimer are 3.19 and 3.45 A. These are considerably longer than the corresponding distances for the Zn(II) enzyme, 2.19 and 2.15 A. The Cu(II) ion is positioned nearly in the plane of the three protein ligands (NS(2)) with a geometry similar to the trigonal arrangement of the three strongly bound ligands (N(2)S) in blue-copper proteins. This coordination probably accounts for the similarity of the spectral characteristics of Cu(II)-LADH and type I copper proteins.

Cd-substituted horse liver alcohol dehydrogenase: catalytic site metal coordination geometry and protein conformation.

The coordination geometry of the catalytic site in Cd-substituted horse liver alcohol dehydrogenase (LADH) has been investigated as a function of pH using the method of perturbed angular correlation of gamma-rays (PAC). LADH in solution fully loaded with cadmium, including radioactive 111mCd in the catalytic site [Cd2(111mCd)Cd2LADH], was studied over the pH range 7.9-11.5. Analysis of the PAC spectra showed the ionization of a group with pKa of 11. This pKa value is about 2 pH units higher than that of native zinc-containing LADH. A pKa of 9.6 was found for the binary complex of Cd2(111mCd)Cd2LADH with NAD+. This value is also about 2 pH units higher than that of the binary complex of native zinc-containing enzyme and NAD+. No pH dependency was detected for the binary complex of Cd2(111mCd)Cd2LADH with NADH within the pH range measured (pH 8.3-11.5). Assuming that metal-coordinated water is the ionizing group [Kvassman, J., & Pettersson, G. (1979) Eur. J. Biochem. 100, 115-123], we conclude that the larger ionic radius of Cd(II) relative to Zn(II) in the catalytic site causes the elevated pKa values of metal-bound water. Interpretation of nuclear quadrupole interaction (NQI) parameters derived from PAC spectra is based on the use of the angular overlap model, using the coordinates for the catalytic zinc site from the 1.8 A resolution crystal structure of the ternary complex between LADH, NADH, and dimethyl sulfoxide as a model.(ABSTRACT TRUNCATED AT 250 WORDS)

Refined crystal structure of liver alcohol dehydrogenase-NADH complex at 1.8 A resolution.

The crystal structure of the ternary complex of horse liver alcohol dehydrogenase (LADH) with the coenzyme NADH and inhibitor dimethyl sulfoxide (DMSO) has been refined by simulated annealing with molecular dynamics and restrained positional refinement using the program X-PLOR. The two subunits of the enzyme were refined independently. The space group was P1 with cell dimensions a = 51.8, b = 44.5, c = 94.6 A, alpha = 104.8, beta = 102.3 and gamma = 70.6 degrees. The resulting crystallographic R factor is 17.3% for 62 440 unique reflections in the resolution range 10.0-1.8 A. A total of 472 ordered solvent molecules were localized in the structure. An analysis of secondary-structure elements, solvent content and NADH binding is presented.

Crystallization and structure determination of bovine profilin at 2.0 A resolution.

Profilin regulates the behavior of the eukaryotic microfilament system through its interaction with non-filamentous actin. It also binds several ligands, including poly(L-proline) and the membrane phospholipid phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P2). Bovine profilin crystals (space group C2; a = 69.15 A, b = 34.59 A, c = 52.49 A; alpha = gamma = 90 degrees, beta = 92.56 degrees) were grown from a mixture of poly(ethylene glycol) 400 and ammonium sulfate. X-ray diffraction data were collected on an imaging plate scanner at the DORIS storage ring (DESY, Hamburg), and were phased by molecular replacement, using a search model derived from the 2.55 A structure of profilin complexed to beta-actin. The refined model of bovine profilin has a crystallographic R-factor of 16.5% in the resolution range 6.0 to 2.0 A and includes 128 water molecules, several of which form hydrogen bonds to stabilize unconventional turns. The structure of free bovine profilin is similar to that of bovine profilin complexed to beta-actin, and C alpha atoms from the two structures superimpose with an r.m.s. deviation of 1.25 A. This value is reduced to 0.51 A by omitting Ala1 and the N-terminal acetyl group, which lie at a profilin-actin interface in crystals of the complex. These residues display a strained conformation in crystalline profilin-actin but may allow the formation of a hydrogen bond between the N-acetyl carbonyl group of profilin and the phenol hydroxyl group of Tyr188 in actin. Several other actin-binding residues of profilin show different side-chain rotomer conformations in the two structures. The polypeptide fold of bovine profilin is generally similar to those observed by NMR for profilin from other sources, although the N terminus of Acanthamoeba profilin isoform I lies in a distorted helix and the C-terminal helix is less tilted with respect to the strands in the central beta-pleated sheet than is observed in bovine profilin. The majority of the aromatic residues in profilin are exposed to solvent and lie in either of two hydrophobic patches, neither of which takes part in an interface with actin. One of these patches is required for binding poly(L-proline) and contains an aromatic cluster comprising the highly conserved residues Trp3, Tyr6, Trp31 and Tyr139. In forming this cluster, Trp31 adopts a sterically strained rotamer conformation.(ABSTRACT TRUNCATED AT 400 WORDS)

Crystal structure of a dUTPase.

The enzyme dUTPase catalyses the hydrolysis of dUTP and maintains a low intracellular concentration of dUTP so that uracil cannot be incorporated into DNA. dUTPase from Escherichia coli is strictly specific for its dUTP substrate, the active site discriminating between nucleotides with respect to the sugar moiety as well as the pyrimidine base. Here we report the three-dimensional structure of E. coli dUTPase determined by X-ray crystallography at a resolution of 1.9 A. The enzyme is a symmetrical trimer, and of the 152 amino acid residues in the subunit, the first 136 are visible in the crystal structure. The tertiary structure resembles a jelly-roll fold and does not show the 'classical' nucleotide-binding domain. In the quaternary structure there is a complex interaction between the subunits that may be important in catalysis. This possibility is supported by the location of conserved elements in the sequence.

Crystallization and preliminary investigation of single crystals of deoxyuridine triphosphate nucleotidohydrolase from Escherichia coli.

Deoxyuridine triphosphate nucleotidohydrolase (dUTPase), an enzyme in the nucleotide metabolism that is a pyrophosphatase hydrolyzing dUTP, has been crystallized. The crystals belong to the trigonal space group R3 and diffract beyond 2 A. The native dUTPase crystals and a mercury derivative are stable in the X-ray beam and are suitable for a high resolution X-ray structure analysis.

Active site specific cadmium(II)-substituted horse liver alcohol dehydrogenase: crystal structures of the free enzyme, its binary complex with NADH, and the ternary complex with NADH and bound p-bromobenzyl alcohol.

Three crystal structures have been determined of active site specific substituted Cd(II) horse liver alcohol dehydrogenase and its complexes. Intensities were collected for the free, orthorhombic enzyme to 2.4-A resolution and for a triclinic binary complex with NADH to 2.7-A resolution. A ternary complex was crystallized from an equilibrium mixture of NAD+ and p-bromobenzyl alcohol. The microspectrophotometric analysis of these single crystals showed the protein-bound coenzyme to be largely NADH, which proves the complex to consist of CdII-LADH, NADH, and p-bromobenzyl alcohol. Intensity data for this abortive ternary complex were collected to 2.9-A resolution. The coordination geometry in the free Cd(II)-substituted enzyme is highly similar to that of the native enzyme. Cd(II) is bound to Cys-46, Cys-174, His-67, and a water molecule in a distorted tetrahedral geometry. Binding of coenzymes induces a conformational change similar to that in the native enzyme. The interactions between the coenzyme and the protein in the binary and ternary complexes are highly similar to those in the native ternary complexes. The substrate binds directly to the cadmium ion in a distorted tetrahedral geometry. No large, significant structural changes compared to the native ternary complex with coenzyme and p-bromobenzyl alcohol were found. The implications of these results for the use of active site specific Cd(II)-substituted horse liver alcohol dehydrogenase as a model system for the native enzyme are discussed.

X-ray analysis of structural changes induced by reduced nicotinamide adenine dinucleotide when bound to cysteine-46-carboxymethylated liver alcohol dehydrogenase.

The structure of the complex between Cys-46-carboxymethylated horse liver alcohol dehydrogenase (CM-LADH) and reduced nicotinamide adenine dinucleotide (NADH) has been determined by X-ray analysis. The complex represents NADH binding to the orthorhombic, "open" conformation of the enzyme. Coenzyme binding here induces a local structural change in the peptide loop 293-297, but there is no domain rotation, as observed for the "closed" conformation of the protein. This local movement of a few residues in the loop is sufficient to trap the nicotinamide ring of NADH within the active-site area close to a productive binding position. The carboxymethyl group on the zinc ligand cysteine-46 is oriented between the pyrophosphate bridge of NADH and the guanidinium group of arginine-369 and can occupy this position because the coenzyme binding cleft remains open and unchanged upon coenzyme binding. The zinc coordination sphere is distorted, and the position of the metal atom is shifted 1 A compared to native unliganded LADH. The distance between the zinc ion and the sulfur of the alkylated cysteine residue is of the order of 3 A. Alkylation experiments were performed at 0.15 and 10 mM iodoacetate, and peptide maps were examined. Gentle treatment with reagent yields an enzyme product which is substituted at only one of the two zinc binding sites per subunit of LADH (Cys-46). This enzyme species maintains its structural integrity; it binds coenzyme which induces conformational changes resolved into two steps. Thus, in addition to the orthorhombic complex, a crystalline NADH complex in the closed conformation of CM-LADH was obtained. These crystals showed enzymic activity, and single crystals were analyzed with microspectrophotometric methods. Formation of the stable crystalline abortive complex between CM-LADH-NAD+ and 4-trans-(N,N-dimethylamino)cinnamaldehyde (DACA) could be observed upon addition of excess aldehyde to the closed complex of CM-LADH-NADH. The CM-LADH-NAD+-DACA complex is characterized by an intense absorption band with a lambda max at 456 nm which corresponds to a shift in the spectrum of free DACA of approximately 60 nm. At the higher concentration of iodoacetate, three of the cysteine ligands to the second zinc atom (Cys-100, -103, and -111) are alkylated in addition to Cys-46. This enzyme product rapidly denatures and cannot be crystallized under our conditions. This is an experimental indication that the intact noncatalytic zinc binding site contributes to the structural stability of the protein.

Reaction of the Z isomer of 4-trans-(N,N-dimethylamino)cinnamaldoxime with the liver alcohol dehydrogenase-oxidized nicotinamide adenine dinucleotide complex.

The Z isomer of 4-trans-(N,N-dimethylamino)-cinnamaldoxime, (Z)-DMOX (lambda maxH2O 354 nm), forms a ternary complex with NAD+ and equine liver alcohol dehydrogenase. The 3-acetyl (3-acetyl-PdAD+), 3-thiocarboxamide (3-thio-NAD+), 3-iodo (io3PdAD+) and nicotinamide mononucleotide (NMN+) analogues of NAD+ also form ternary complexes with enzyme and (Z)-DMOX. These complexes are characterized by large red-shifts in the UV-visible spectrum of bound (Z)-DMOX (lambda max 428 nm for the NAD+ complex) and new spectral bands in the 280-340-nm region associated with the pyridine moieties of NAD+ and the NAD+ analogues. The ternary enzyme-NAD+-(Z)-DMOX complex is weakly fluorescent (lambda ex 430 nm; lambda em max 505 nm) and strongly quenches the residual tryptophan fluorescence of the enzyme-NAD+ binary complex. (Z)-DMOX binds with high affinity to the enzyme-NAD+ complex (Kd less than or equal to 4 X 10(-9) M at pH 8.75 and 25 degrees C), and similarly high affinities were found for the 3-acetyl-PdAD+, 3-thio-NAD+, and io3PdAD+ complexes. Binding is much weaker to the enzyme-NMN+ complex. The active site specifically substituted Co(II), Ni(II), Cu(II), and Cd(II) enzyme derivatives and the enzyme species lacking any metal ion at the active site (apoenzyme) also form ternary complexes with (Z)-DMOX in which the DMOX UV-visible spectrum is red-shifted (ranging from 43 to 83.5 nm). The complexes formed with the Zn(II) and Co(II) enzymes are characterized by relatively high affinities for (Z)-DMOX and by spectra that are independent of pH over the range 6-10. The affinity of the apoenzyme-NAD+ complex for (Z)-DMOX is much lower, and the spectrum of the complex is pH dependent with lambda max = 430 nm at pH 7 and lambda max = 397 nm at pH 10. The rate of (Z)-DMOX dissociation from the apoenzyme complex was found to be approximately 10(3)-fold greater than the rates observed for the metal ion substituted enzymes. The 280-340-nm spectral bands appear to result from the dihydropyridine moieties of covalent adducts formed between (Z)-DMOX and NAD+ and the NAD+ analogues. The large red-shifts of the (Z)-DMOX spectrum result from the bonding of the oxime nitrogen to a strong electrophilic center (either the active site zinc ion or the nicotinamide ring of NAD+.)(ABSTRACT TRUNCATED AT 400 WORDS)

Crystallization and preliminary x-ray studies of spinach ribulose 1,5-bisphosphate carboxylase/oxygenase complexed with activator and a transition state analogue.

Ribulose 1,5-bisphosphate carboxylase/oxygenase has been purified from spinach and crystallized by equilibrium vapor diffusion with polyethylene glycol 6000 as a precipitant. Crystals suitable for x-ray studies were obtained from a binary complex with a transition state analogue, 2-C-carboxy-D-arabinitol 1,5-bisphosphate, and a quaternary complex with 2-C-carboxy-D-arabinitol 1,5-bisphosphate, Mg2+, and HCO-3. Two forms of crystals were obtained in the presence of 2-C-carboxy-D-arabinitol 1,5-bisphosphate. Form B crystals are plates which have orthorhombic space group P2(1)2(1)2 with unit cell dimensions a = 184 A, b = 218 A, and c = 119 A. Form C crystals are tetragonal needles with space group I422 and with cell dimensions a = b = 275 A and c = 178 A. In both forms, the asymmetric unit contains half a molecule.

Crystal-structure determination of reduced nicotinamide adenine dinucleotide complex with horse liver alcohol dehydrogenase maintained in its apo conformation by zinc-bound imidazole.

A crystallographic study to 2.4-A resolution of the ternary complex between horse liver alcohol dehydrogenase (LADH), NADH, and the effector molecule imidazole (Im) (LADH-NADH-Im) is presented. The ligand binding and the changes in the protein structure due to ligand interactions were interpreted from difference electron density maps calculated with phase angles derived from the refined native enzyme model. The complex crystallizes in the orthorhombic space group C2221, and the enzyme structure remains in the apo conformation in which the active-site cleft is not entirely shielded from the solvent. NADH binds in an extended conformation, and the protein-coenzyme interactions are weaker compared to other complexes. The B-stereospecific side of the nicotinamide ring faces the catalytic center (LADH is known to be an A-side-specific enzyme). However, the reactive carbon atom C4 of the ring has a similar position in relation to active-center groups in this structure compared to LADH complexes where the A side of the ring faces the substrate site. The carboxamide group is situated within hydrogen-bonding distance to the sulfur of Cys-46, which is one of the three protein ligands to the active-site zinc atom. The imidazole molecule is directly ligated to the metal ion, which has a roughly tetrahedral geometry in the complex.