Microspectrophotometric studies on single crystals of the tryptophan synthase alpha 2 beta 2 complex demonstrate formation of enzyme-substrate intermediates

Microspectrophotometry of single crystals of the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium is used to compare the catalytic and regulatory properties of the enzyme in the soluble and crystalline states. Polarized absorption spectra demonstrate that chromophoric intermediates are formed between pyridoxal phosphate at the active site of the beta subunit and added substrates, substrate analogs, and reaction intermediate analogs. Although the crystalline and soluble forms of the enzyme produce some of the same enzyme-substrate intermediates, including Schiff base and quinonoid intermediates, in some cases the equilibrium distribution of these intermediates differs in the two states of the enzyme. Ligands which bind to the active site of the alpha subunit alter the distribution of intermediates formed at the active site of the beta subunit in both the crystalline and soluble states. The three-dimensional structures of the tryptophan synthase alpha 2 beta 2 complex and of a derivative with indole-3-propanol phosphate bound at the active site of the alpha subunit have recently been reported (Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., and Davies, D. R. (1988) J. Biol. Chem. 264, 17857-17871). Our present findings help to establish experimental conditions for selecting defined intermediates for future x-ray crystallographic analysis of the alpha 2 beta 2 complex with ligands bound at the active sites of both alpha and beta subunits. These crystallographic studies should explain how catalysis occurs at the active site of the beta subunit and how the binding of a ligand to one active site affects the binding of a ligand to the other active site which is 25 A away.     

Catalytic activity of non-cross-linked microcrystals of aspartate aminotransferase in poly(ethylene glycol).

The molar activity of crystalline mitochondrial aspartate aminotransferase is decreased to 10% of that of the enzyme in solution. The activity was measured in suspensions of non-cross-linked microcrystals (average dimensions 22 microns X 5 microns X 0.8 microns) in 30% (w/v) poly(ethylene glycol). Kinetic tests ruled out the possibility that diffusion of the substrate in the crystals is rate-limiting. The observed decrease in catalytic efficiency can be attributed exclusively to crystal-packing effects. A direct inhibition by poly(ethylene glycol) is excluded because poly(ethylene glycol), with average Mr 6000, cannot penetrate the liquid channels of the crystals, owing to its large Stokes radius. The crystals examined were triclinic and of the same habit as those used for high-resolution X-ray-crystallographic analysis [Ford, Eichele & Jansonius (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 2559-2563]. The catalytic competence of crystalline aspartate aminotransferase confirms the relevance of the spatial model of this protein for the elucidation of its mechanism of action.     

Equilibrium kinetics of substrate-enzyme interactions in single crystals of cytoplasmic aspartate aminotransferase

Orthorhombic single crystals of cytoplasmic aspartate aminotransferase were examined alone or in the presence of substrates or inhibitors to quantitatively compare the interaction of ligands with the active-site chromophore between soluble and crystalline enzyme. As in enzyme solutions, equilibrium kinetic measurements can be made between substrates and single crystals of cytoplasmic aspartate aminotransferase. The absorption spectra of ligand-free enzyme forms and of enzyme-substrate or-inhibitor complexes are as distinctive as when the enzyme is in solution. The dissociation constants for glutamate with the pyridoxal form of the enzyme are identical to those in solution. The substrate analog erythro--hydroxyaspartate also binds with equal affinity to the active site in enzyme crystals as in solution; and the affinity of -ketoglutarate to bind in nonproductive complexes with the pyridoxal form of the enzyme is also unimpaired in the crystal (K _d =2 mM). In contrast to the affinity constants, the stoichiometry of the interactions does not appear to correlate to those in solution. In the presence of an amino acid plus keto acid substrates pair, the absorbance values of the enzyme-substrate complex(es) could be interpreted as for occupany of only half the available sites in the crystals. Yet an amino acid, cysteine sulfinate, and -keto acids such as , -difluorooxalacetate convert all active sites in the crystal to the pyridoxamine or pyridoxal form when added to the pyridoxal or pyridoxamine forms, respectively. This ability to completely undergo substrate-induced half-transamination and the apparently conflicting results in trapping half the sites in enzyme-substrate complexes are incorporated into a proposed reciprocating mechanism applicable only to the crystalline state of the enzyme and dictated by crystal packing forces rather than an intrinsic property of the enzyme. Active-site bound pyridoxal phosphate continues to behave as a pH indicator; nevertheless, the pK value of the single crystals is a pH unit (pK=7.15) higher than that in solution. This variation is interpreted as indication of a difference in the environment of the chromophore between the crystal and solution states. While the environmental difference does not significantly alter the affinity for substrates, it could account for the reduced rates in transformation of the enzyme-substrate complexes in half-transamination reactions in the crystalline state.     

The catalytic activity of muscle phosphoglucomutase in the crystalline phase

A suspension of microcrystals of phosphoglucomutase in 60% ammonium sulfate exhibits a maximal catalytic activity in substrate-velocity studies that is about 0.2 of that obtained with the soluble enzyme under the same conditions. The apparent Michaelis constants for the reaction in the crystal phase are altered to an even smaller extent, relative to that in solution, although the parameters for the monophosphate and bisphosphate are increased more than 3 and more than 5 orders of magnitude, respectively, by the sulfate present. The compatibility of larger crystals with a reaction that constitutes part of the catalytic process also is demonstrated.     

The alpha beta-methylene analogues of ADP and ATP act as substrates for creatine kinase. delta G0 for this reaction and for the hydrolysis of the alpha beta-methylene analogue of ATP

The alpha beta-methylene analogues of ATP and ADP, [alpha beta CH2]ATP and [alpha beta CH2]ADP, are substrates for creatine kinase. However, the rate of the phosphoryl transfer reaction catalysed is about 10(-5)-times lower than that with normal ATP. The affinities of the analogues (especially [alpha beta CH2]ADP) for the enzyme are lower than those of the normal substrates. The equilibrium constant at 25 degrees C, measured using 31P NMR, for the reaction Mg[alpha beta CH2]ATP + creatine in equilibrium Mg[alpha beta CH2]ADP + phosphocreatine + H+ is 2.2 X 10(-12) M compared with a value of 2.5 X 10(-10) M for the same reaction with the normal substrates, corresponding to a difference in delta G0 values of 11.7 kJ X mol-1. It follows that delta G0 for the hydrolysis of the terminal phosphate group of Mg[alpha beta CH2]ATP is less favourable by 11.7 kJ X mol-1 than that for MgATP.     

Xenon and halogenated alkanes track putative substrate binding cavities in the soluble methane monooxygenase hydroxylase

To investigate the role of protein cavities in facilitating movement of the substrates, methane and dioxygen, in the soluble methane monooxygenase hydroxylase (MMOH), we determined the X-ray structures of MMOH from Methylococcus capsulatus (Bath) cocrystallized with dibromomethane or iodoethane, or by using crystals pressurized with xenon gas. The halogenated alkanes bind in two cavities within the alpha-subunit that extend from one surface of the protein to the buried dinuclear iron active site. Two additional binding sites were located in the beta-subunit. Pressurization of two crystal forms of MMOH with xenon resulted in the identification of six binding sites located exclusively in the alpha-subunit. These results indicate that hydrophobic species bind preferentially in preexisting cavities in MMOH and support the hypothesis that such cavities may play a functional role in sequestering and enhancing the availability of the physiological substrates for reaction at the active site.     

Crystal structure of the dimeric phosphoenolpyruvate carboxykinase (PEPCK) from Trypanosoma cruzi at 2 A resolution.

ATP-dependent phosphoenolpyruvate carboxykinase (PEPCK) (ATP: oxaloacetate carboxylyase (transphosphorylating), EC 4.1.1.49) is a key enzyme involved in the catabolism of glucose and amino acids in the parasite Trypanosoma cruzi, the causative agent of Chagas' disease. Due to the significant differences in the amino acid sequence and substrate specificity of the human enzyme (PEPCK (GTP-dependent), EC 4.1.1.32), the parasite enzyme has been considered a good target for the development of new anti-chagasic drugs. We have solved the crystal structure of the recombinant PEPCK of T. cruzi up to 2.0 A resolution, characterised the dimeric organisation of the enzyme by solution small angle X-ray scattering (SAXS) and compared the enzyme structure with the known crystal structure of the monomeric PEPCK from Escherichia coli. The dimeric structure possesses 2-fold symmetry, with each monomer sharing a high degree of structural similarity with the monomeric structure of the E. coli PEPCK. Each monomer folds into two complex mixed alpha/beta domains, with the active site located in a deep cleft between the domains. The two active sites in the dimer are far apart from each other, in an arrangement that seems to permit an independent access of the substrates to the two active sites. All residues of the E. coli PEPCK structure that had been found to interact with substrates and metal cofactors have been found conserved and in a substantially equivalent spatial disposition in the T. cruzi PEPCK structure. No substrate or metal ion was present in the crystal structure. A sulphate ion from the crystallisation medium has been found bound to the active site. Solution SAXS data suggest that, in solutions with lower sulphate concentration than that used for the crystallisation experiments, the actual enzyme conformation may be slightly different from its conformation in the crystal structure. This could be due to a conformational transition upon sulphate binding, similar to the ATP-induced transition observed in the E. coli PEPCK, or to crystal packing effects. The present structure of the T. cruzi PEPCK will provide a good basis for the modelling of new anti-chagasic drug leads.     

Crystalline enzyme.substrate complexes of asparate aminotransferase

Crystalline complexes of cytoplasmic aspartate aminotransferase of pig heart with the substrates L-glutamate and L-aspartate, and with other amino acids, have been prepared and polarized light absorption spectra have been measured. Striking differences in the directions of polarization of the absorption bands are seen. A complete half-transamination of pyridoxal phosphate to pyridoxamine phosphate by aspartate or by cysteine sulfinate can be demonstrated in the crystal as can the accumulation of a quinonoid intermediate with erythro-beta-hydroxyaspartate. X-ray diffraction studies show that the crystals with erythro-beta-hydroxyaspartate and alpha-methylaspartate are isomorphous with those of both alpha and beta subforms of the native enzyme.     

Metastability and transformation of polymorphic crystals in biodegradable poly(butylene adipate)

Polymorphism phenomenon of melt-crystallized poly(butylene adipate) (PBA) has been studied by wide-angle X-ray diffraction (WAXD), small-angle X-ray scattering (SAXS), and differential scanning calorimetry (DSC). It has been found that the isothermal crystallization leads to the formation of PBA polymorphic crystals, simply by changing the crystallization temperature. The PBA alpha crystal, beta crystal, and the mixture of two crystal forms grow at the crystallization temperatures above 32 degrees C, below 27 degrees C, and between these two temperatures, respectively. The relationship between PBA polymorphism and melting behaviors has been analyzed by the assignments of multiple melting peaks. Accordingly, the equilibrium melting temperatures Tm degrees of both alpha and beta crystals were determined by Hoffman-Weeks and Gibbs-Thomson equations for the purpose of understanding the structural metastability. The Tm degrees of the PBA alpha crystal was found to be higher than that of the beta crystal, indicating that the PBA alpha crystal form is a structurally stable phase and that the beta crystal form is a metastable phase. The analysis of growth kinetics of PBA polymorphic crystals indicates that the metastable PBA beta crystal is indeed the kinetically preferential result. Based on the thermal and kinetic results, the phenomenon of stability inversion with crystal size in melt-crystallized PBA was recognized, in terms of the growth mechanisms of PBA alpha and beta crystals and the transformation of beta to alpha crystals. The PBA beta --> alpha crystal transformation takes place at a sufficiently high annealing temperature, and the transformation has been evident to be a solid-solid-phase transition process accompanied by the thickening of lamellar crystals. The molecular motion of polymer chains in both crystalline and amorphous phases has been discussed to understand the thickening and phase transformation behaviors.     

Production of human prolyl 4-hydroxylase in Escherichia coli

Prolyl 4-hydroxylase (P4H) catalyzes the post-translational hydroxylation of proline residues in collagen strands. The enzyme is an alpha2beta2 tetramer in which the alpha subunits contain the catalytic active sites and the beta subunits (protein disulfide isomerase) maintain the alpha subunits in a soluble and active conformation. Heterologous production of the native alpha2beta2 tetramer is challenging and had not been reported previously in a prokaryotic system. Here, we describe the production of active human P4H tetramer in Escherichia coli from a single bicistronic vector. P4H production requires the relatively oxidizing cytosol of Origami B(DE3) cells. Induction of the wild-type alpha(I) cDNA in these cells leads to the production of a truncated alpha subunit (residues 235-534), which assembles with the beta subunit. This truncated P4H is an active enzyme, but has a high Km value for long substrates. Replacing the Met235 codon with one for leucine removes an alternative start codon and enables production of full-length alpha subunit and assembly of the native alpha2beta2 tetramer in E. coli cells to yield 2 mg of purified P4H per liter of culture (0.2 mg/g of cell paste). We also report a direct, automated assay of proline hydroxylation using high-performance liquid chromatography. We anticipate that these advances will facilitate structure-function analyses of P4H.     

Preliminary crystallographic study of the phenylalanyl-tRNA synthetase from Thermus thermophilus HB8

Phenylalanyl-tRNA synthetase (EC 6.1.1.20) from the extreme thermophile Thermus thermophilus HB8 has been isolated and crystallized. The enzyme was found to consist of two types of subunits with molecular masses 38 X 10(3) (alpha) and 94 X 10(3) (beta) and is likely to be a tetrameric protein with a molecular mass of about 260 X 10(3) (alpha 2 beta 2). Crystals of phenylalanyl-tRNA synthetase were grown by the hanging-drop technique at 4 degrees C in the presence of ammonium sulfate. Trigonal crystals, space group P3(1)21, with cell dimensions a = b = 176 A and c = 142 A (1 A = 0.1 nm), are suitable for medium-resolution X-ray analysis.     

Crystal structure of thiamin phosphate synthase from Bacillus subtilis at 1.25 A resolution.

The crystal structure of Bacillus subtilis thiamin phosphate synthase complexed with the reaction products thiamin phosphate and pyrophosphate has been determined by multiwavelength anomalous diffraction phasing techniques and refined to 1.25 A resolution. Thiamin phosphate synthase is an alpha/beta protein with a triosephosphate isomerase fold. The active site is in a pocket formed primarily by the loop regions, residues 59-67 (A loop, joining alpha3 and beta2), residues 109-114 (B loop, joining alpha5 and beta4), and residues 151-168 (C loop, joining alpha7 and beta6). The high-resolution structure of thiamin phosphate synthase complexed with its reaction products described here provides a detailed picture of the catalytically important interactions between the enzyme and the substrates. The structure and other mechanistic studies are consistent with a reaction mechanism involving the ionization of 4-amino-2-methyl-5-hydroxymethylpyrimidine pyrophosphate at the active site to give the pyrimidine carbocation. Trapping of the carbocation by the thiazole followed by product dissociation completes the reaction. The ionization step is catalyzed by orienting the C-O bond perpendicular to the plane of the pyrimidine, by hydrogen bonding between the C4' amino group and one of the terminal oxygen atoms of the pyrophosphate, and by extensive hydrogen bonding and electrostatic interactions between the pyrophosphate and the enzyme.     

Analysis of the class I aldolase binding site architecture based on the crystal structure of 2-deoxyribose-5-phosphate aldolase at 0.99A resolution

The crystal structure of the bacterial (Escherichia coli) class I 2-deoxyribose-5-phosphate aldolase (DERA) has been determined by Se-Met multiple anomalous dispersion (MAD) methods at 0.99A resolution. This structure represents the highest-resolution X-ray structure of an aldolase determined to date and enables a true atomic view of the enzyme. The crystal structure shows the ubiquitous TIM alpha/beta barrel fold. The enzyme contains two lysine residues in the active site. Lys167 forms the Schiff base intermediate, whereas Lys201, which is in close vicinity to the reactive lysine residue, is responsible for the perturbed pK(a) of Lys167 and, hence, also a key residue in the reaction mechanism. DERA is the only known aldolase that is able to use aldehydes as both aldol donor and acceptor molecules in the aldol reaction and is, therefore, of particular interest as a biocatalyst in synthetic organic chemistry. The uncomplexed DERA structure enables a detailed comparison with the substrate complexes and highlights a conformational change in the phosphate-binding site. Knowledge of the enzyme active-site environment has been the basis for exploration of catalysis of non-natural substrates and of mutagenesis of the phosphate-binding site to expand substrate specificity. Detailed comparison with other class I aldolase enzymes and DERA enzymes from different organisms reveals a similar geometric arrangement of key residues and implies a potential role for water as a general base in the catalytic mechanism.     

Mechanical stability of immobilized biocatalysts (CLECs) in dilute agitated suspensions

Cross-linked enzyme crystals (CLECs) are a novel form of immobilized biocatalyst designed for application in industrial biotransformation processes. In this work we have investigated the mechanical stability of agitated CLEC suspensions in relation to the design and scale-up of bioconversions carried out in stirred-tank reactors. By careful control of the crystallization conditions yeast alcohol dehydrogenase I (YADHI) microcrystals of different size were first prepared having either an hexagonal (approximately 12 microm) or rod-shaped (approximately 4.6 microm) morphology. These were then cross-linked with glutaraldehyde to form CLECs. The rate of breakage of the CLEC suspensions was subsequently measured in a rotating disk shear device (total volume, 11 mL) by monitoring the change in crystal size distribution with time. This device is designed to mimic the shear and energy dissipation rates found in a range of process scale equipment and may be used to study the mechanical stability of any immobilized biocatalyst preparation. Experiments were performed as a function of the speed and duration of disk rotation, CLEC concentration (0.26-2.5 mg.mL(-1)) and energy dissipation rate (2.2 x 10(3) to 6.8 x 10(5) W.kg(-1)). No breakage of the rod-shaped CLECs was observed over the entire range of experimental conditions investigated. Breakage of the larger hexagonal-shaped CLECs did occur, however, at energy dissipation rates, epsilon(max), above 1.0 x 10(5) W.kg(-1), where the calculated length scale of turbulence was around 2.0 microm. Based on visual observation of the sheared CLEC suspensions and models of crystal breakage, it was concluded that breakage of the hexagonal-shaped CLECs occurred due to shear induced attrition. Measurement of the catalytic activity of both the hexagonal and rod-shaped CLECs showed no significant change in activity before and after shearing.     

Oxygen binding by alpha(Fe2+)2beta(Ni2+)2 hemoglobin crystals

Oxygen binding by hemoglobin fixed in the T state either by crystallization or by encapsulation in silica gels is apparently noncooperative. However, cooperativity might be masked by different oxygen affinities of alpha and beta subunits. Metal hybrid hemoglobins, where the noniron metal does not bind oxygen, provide the opportunity to determine the oxygen affinities of alpha and beta hemes separately. Previous studies have characterized the oxygen binding by alpha(Ni2+)2beta(Fe2+)2 crystals. Here, we have determined the three-dimensional (3D) structure and oxygen binding of alpha(Fe2+)2beta(Ni2+)2 crystals grown from polyethylene glycol solutions. Polarized absorption spectra were recorded at different oxygen pressures with light polarized parallel either to the b or c crystal axis by single crystal microspectrophotometry. The oxygen pressures at 50% saturation (p50s) are 95 +/- 3 and 87 +/- 4 Torr along the b and c crystal axes, respectively, and the corresponding Hill coefficients are 0.96 +/- 0.06 and 0.90 +/- 0.03. Analysis of the binding curves, taking into account the different projections of the alpha hemes along the optical directions, indicates that the oxygen affinity of alpha1 hemes is 1.3-fold lower than alpha2 hemes. Inspection of the 3D structure suggests that this inequivalence may arise from packing interactions of the Hb tetramer within the monoclinic crystal lattice. A similar inequivalence was found for the beta subunits of alpha(Ni2+)2beta(Fe2+)2 crystals. The average oxygen affinity of the alpha subunits (p50 = 91 Torr) is about 1.2-fold higher than the beta subunits (p50 = 110 Torr). In the absence of cooperativity, this heterogeneity yields an oxygen binding curve of Hb A with a Hill coefficient of 0.999. Since the binding curves of Hb A crystals exhibit a Hill coefficient very close to unity, these findings indicate that oxygen binding by T-state hemoglobin is noncooperative, in keeping with the Monod, Wyman, and Changeux model.     

Crystal structure of Escherichia coli glucose-1-phosphate thymidylyltransferase (RffH) complexed with dTTP and Mg2+

The enzyme glucose-1-phosphate thymidylyltransferase (RffH), the product of the rffh gene, catalyzes one of the steps in the synthesis of enterobacterial common antigen (ECA), a cell surface glycolipid found in Gram-negative enteric bacteria. In Escherichia coli two gene products, RffH and RmlA, catalyze the same enzymatic reaction and are homologous in sequence; however, they are part of different operons and function in different pathways. We report the crystal structure of RffH bound to deoxythymidine triphosphate (dTTP), the phosphate donor, and Mg(2+), refined at 2.6 A to an R-factor of 22.3% (R(free) = 28.4%). The crystal structure of RffH shows a tetrameric enzyme best described as a dimer of dimers. Each monomer has an overall alpha/beta fold and consists of two domains, a larger nucleotide binding domain (residues 1-115, 222-291) and a smaller sugar-binding domain (116-221), with the active site located at the domain interface. The Mg(2+) ion is coordinated by two conserved aspartates and the alpha-phosphate of deoxythymidine triphosphate. Its location corresponds well to that in a structurally similar domain of N-acetylglucosamine-1-phosphate uridylyltransferase (GlmU). Analysis of the RffH, RmlA, and GlmU complexes with substrates and products provides an explanation for their different affinities for Mg(2+) and leads to a proposal for the dynamics along the reaction pathway.     

DNA inhibits catalysis by the carboxyltransferase subunit of acetyl-CoA carboxylase: implications for active site communication

Acetyl-CoA carboxylase (ACC) catalyzes the first committed step in the synthesis of long-chain fatty acids. The crystal structure of the Escherichia coli carboxyltransferase component of ACC revealed an alpha(2)beta(2) subunit composition with two active sites and, most importantly, a unique zinc domain in each alphabeta pair that is absent in the eukaryotic enzyme. We show here that carboxyltransferase binds DNA. Half-maximal saturation of different single-stranded or double-stranded DNA constructs is seen at 0.5-1.0 muM, and binding is cooperative and nonspecific. The substrates (malonyl-CoA and biocytin) inhibit DNA:carboxyltransferase complex formation. More significantly, single-stranded DNA, double-stranded DNA, and heparin inhibit the reaction catalyzed by carboxyltransferase, with single-stranded DNA and heparin acting as competitive inhibitors. However, double-inhibition experiments revealed that both DNA and heparin can bind the enzyme in the presence of a bisubstrate analog (BiSA), and the binding of BiSA has a very weak synergistic effect on the binding of the second inhibitor (DNA or heparin) and vice versa. In contrast, DNA and heparin can also bind to the enzyme simultaneously, but the binding of either molecule has a strong synergistic effect on binding of the other. An important mechanistic implication of these observations is that the dual active sites of ACC are functionally connected.     

The crystal structure of coenzyme B12-dependent glycerol dehydratase in complex with cobalamin and propane-1,2-diol.

Recombinant glycerol dehydratase of Klebsiella pneumoniae was purified to homogeneity. The subunit composition of the enzyme was most probably alpha 2 beta 2 gamma 2. When (R)- and (S)-propane-1,2-diols were used independently as substrates, the rate with the (R)-enantiomer was 2.5 times faster than that with the (S)-isomer. In contrast to diol dehydratase, an isofunctional enzyme, the affinity of the enzyme for the (S)-isomer was essentially the same or only slightly higher than that for the (R)-isomer (Km(R)/Km(S) = 1.5). The crystal structure of glycerol dehydratase in complex with cyanocobalamin and propane-1,2-diol was determined at 2.1 A resolution. The enzyme exists as a dimer of the alpha beta gamma heterotrimer. Cobalamin is bound at the interface between the alpha and beta subunits in the so-called 'base-on' mode with 5,6-dimethylbenzimidazole of the nucleotide moiety coordinating to the cobalt atom. The electron density of the cyano group was almost unobservable, suggesting that the cyanocobalamin was reduced to cob(II)alamin by X-ray irradiation. The active site is in a (beta/alpha)8 barrel that was formed by a central region of the alpha subunit. The substrate propane-1,2-diol and essential cofactor K+ are bound inside the (beta/alpha)8 barrel above the corrin ring of cobalamin. K+ is hepta-coordinated by the two hydroxyls of the substrate and five oxygen atoms from the active-site residues. These structural features are quite similar to those of diol dehydratase. A closer contact between the alpha and beta subunits in glycerol dehydratase may be reminiscent of the higher affinity of the enzyme for adenosylcobalamin than that of diol dehydratase. Although racemic propane-1,2-diol was used for crystallization, the substrate bound to glycerol dehydratase was assigned to the (R)-isomer. This is in clear contrast to diol dehydratase and accounts for the difference between the two enzymes in the susceptibility of suicide inactivation by glycerol.     

The crystal structure of the complex of Zea mays alpha subunit with a fragment of human beta subunit provides the clue to the architecture of protein kinase CK2 holoenzyme.

The crystal structure of a complex between the catalytic alpha subunit of Zea mays CK2 and a 23-mer peptide corresponding the C-terminal sequence 181-203 of the human CK2 regulatory beta subunit has been determined at 3.16-A resolution. The complex, composed of two alpha chains and two peptides, presents a molecular twofold axis, with each peptide interacting with both alpha chains. In the derived model of the holoenzyme, the regulatory subunits are positioned on the opposite side with respect to the opening of the catalytic sites, that remain accessible to substrates and cosubstrates. The beta subunit can influence the catalytic activity both directly and by promoting the formation of the alpha2 dimer, in which each alpha chain interacts with the active site of the other. Furthermore, the two active sites are so close in space that they can simultaneously bind and phosphorylate two phosphoacceptor residues of the same substrate.     

Structural basis of proline-specific exopeptidase activity as observed in human dipeptidyl peptidase-IV

Inhibition of dipeptidyl peptidase IV (DPP-IV), the main glucagon-like peptide 1 (GLP1)-degrading enzyme, has been proposed for the treatment of type II diabetes. We expressed and purified the ectodomain of human DPP-IV in Pichia pastoris and determined the X-ray structure at 2.1 A resolution. The enzyme consists of two domains, the catalytic domain, with an alpha/beta hydrolase fold, and a beta propeller domain with an 8-fold repeat of a four-strand beta sheet motif. The beta propeller domain contributes two important functions to the molecule that have not been reported for such structures, an extra beta sheet motif that forms part of the dimerization interface and an additional short helix with a double Glu sequence motif. The Glu motif provides recognition and a binding site for the N terminus of the substrates, as revealed by the complex structure with diprotin A, a substrate with low turnover that is trapped in the tetrahedral intermediate of the reaction in the crystal.