Advances in Enzymology and Related Subjects最新文献

The enzymes phenylalanine hydroxylase, tyrosine hydroxylase, and tryptophan hydroxylase constitute the family of pterin-dependent aromatic amino acid hydroxylases. Each enzyme catalyzes the hydroxylation of the aromatic side chain of its respective amino acid substrate using molecular oxygen and a tetrahydropterin as substrates. Recent advances have provided insights into the structures, mechanisms, and regulation of these enzymes. The eukaryotic enzymes are homotetramers comprised of homologous catalytic domains and discrete regulatory domains. The ligands to the active site iron atom as well as residues involved in substrate binding have been identified from a combination of structural studies and site-directed mutagenesis. Mechanistic studies with nonphysiological and isotopically substituted substrates have provided details of the mechanism of hydroxylation. While the complex regulatory properties of phenylalanine and tyrosine hydroxylase are still not fully understood, effects of regulation on key kinetic parameters have been identified. Phenylalanine hydroxylase is regulated by an interaction between phosphorylation and allosteric regulation by substrates. Tyrosine hydroxylase is regulated by phosphorylation and feedback inhibition by catecholamines.

The 31P NMR data suggest slight differences in the structures around the 5'-P for the internal Schiff base and the lanthionine external Schiff base (both largely ketoeneamine) and a large difference for enolimine portion of the serine external Schiff base. Addition of cysteine or serine increase delayed fluorescence and triplet to singlet energy transfer. Addition of OAS exhibits a splitting of the 0,0 vibronic, the result of two distinct conformations, likely enolimine and ketoeneamine tautomers. Nonetheless, the alpha-amino-acrylate Schiff base conformation differs from either the internal or external Schiff base conformations. All of the time-resolved fluorescence data are consistent with conformation changes reflecting redistribution of ketoeneamine and enolimine tautomers as catalysis occurs. It is important to remember that the structural changes are substantial. The native structure (internal Schiff base) is active site open, while the K41A mutant enzyme (ketoeneamine external Schiff base) is active site closed. The trigger for the conformational change from open to closed as one goes from the internal to external Schiff base is the occupancy of the alpha-carboxyl subsite of the active site (Burkhard et al., 1999). Associated with this, as observed in pH-rate profiles, pH-dependent changes in phosphorescence, and pH-dependent changes in fluorescence enhancement upon binding acetate or cysteine is an enzyme group with a pK in the range 7-8. Dependent on the protonation state of the enzyme group, structural changes likely occur that also reflect a redistribution of the tautomeric equilibrium. Finally, the minimal catalytic cycle can likely be pictured as shown in Fig. 20. The changes may be pH dependent, and the open conformations for the internal Schiff base and the alpha-aminoacrylate Schiff base are not identical structurally, as expected because of the increased stability of the latter.

The pyridoxal-5-phosphate-dependent enzymes (B6 enzymes) that act on amino acid substrates are of multiple evolutionary origin. The numerous common mechanistic features of B6 enzymes thus are not historical traits passed on from a common ancestor enzyme but rather reflect evolutionary or chemical necessities. Family profile analysis of amino acid sequences supported by comparison of the available three-dimensional (3-D) crystal structures indicates that the B6 enzymes known to date belong to four independent evolutionary lineages of homologous (or more precisely paralogous) proteins, of which the alpha family is by far the largest. The alpha family (with aspartate aminotransferase as the prototype enzyme) includes enzymes that catalyze, with several exceptions, transformations of amino acids in which the covalency changes are limited to the same carbon atom that carries the amino group forming the imine linkage with the coenzyme (i.e., Calpha in most cases). Enzymes of the beta family (tryptophan synthase beta as the prototype enzyme) mainly catalyze replacement and elimination reactions at Cbeta. The D-alanine aminotransferase family and the alanine racemase family are the two other independent lineages, both with relatively few member enzymes. The primordial pyridoxal-5-phosphate-dependent enzymes apparently were regio-specific catalysts that first diverged into reaction-specific enzymes and then specialized for substrate specificity. Aminotransferases as well as amino acid decarboxylases are found in two different evolutionary lineages. Comparison of sequences from eukaryotic, archebacterial, and eubacterial species indicates that the functional specialization of most B6 enzymes has occurred already in the universal ancestor cell. The cofactor pyridoxal-5-phosphate must have emerged very early in biological evolution; conceivably, organic cofactors and metal ions were the first biological catalysts. In attempts to stimulate particular steps of molecular evolution, oligonucleotide-directed mutagenesis of active-site residues and directed molecular evolution have been applied to change both the substrate and reaction specificity of existent B6 enzymes. Pyridoxal-5-phosphate-dependent catalytic antibodies were elicited with a screening protocol that applied functional selection criteria as they might have been operative in the evolution of protein-assisted pyridoxal catalysis.

By exerting strategic control on purine nucleotide biosynthesis, and by engaging GTP-dependent transphosphorylation of IMP to activate loss of an oxygen atom during catalysis, adenylosuccinate synthetase remains as enzyme that justifiably fascinates students of enzyme catalysis. This review describes how the balanced application of X-ray crystallography and enzyme kinetics has advanced the comprehension of the catalytic and regulatory properties of adenylosuccinate synthetase. Detailed analysis has demonstrated the formation of 6-phosphoryl-IMP, an intermediate originally postulated over 40 years ago on the basis of oxygen-18 exchange experiments showing that position-6 oxygen of IMP becomes incorporated into phosphate. Inferences about the participation of amino acid side-chains that stabilize 6-P-IMP during catalysis have also been confirmed by site-directed mutagenesis and examination of such mutations on various kinetic parameters. Moreover, the action of certain regulatory ligands have also been viewed at atomic level resolution. For example, magnesium ion and GDP can induce conformational changes linked to the stabilization of one of two known conformations of the so-called 40s loop. Another significant finding is that two magnesium ions play fundamental roles: one binding with high affinity to the substrate GTP, and a second binding with lower affinity to the co-substrate aspartate. These structural and kinetic studies have also formed the basis for clarifying the action of various inhibitors and potentially important pharmacologic agents with this key regulatory enzyme. Finally, this review explores the current status of investigations on gene structure and gene expression in a number of organisms.

Beyond its role as an essential coenzyme in numerous oxidoreductase reactions as well as respiration, there is growing recognition that NAD+ fulfills many other vital regulatory functions both as a substrate and as an allosteric effector. This review describes the enzymes involved in pyridine nucleotide metabolism, starting with a detailed consideration of the anaerobic and aerobic pathways leading to quinolinate, a key precursor of NAD+. Conversion of quinolinate and 5'-phosphoribosyl-1'-pyrophosphate to NAD+ and diphosphate by phosphoribosyltransferase is then explored before proceeding to a discussion the molecular and kinetic properties of NMN adenylytransferase. The salient features of NAD+ synthetase as well as NAD+ kinase are likewise presented. The remainder of the review encompasses the metabolic steps devoted to (a) the salvaging of various niacin derivatives, including the roles played by NAD+ and NADH pyrophosphatases, nicotinamide deamidase, and NMN deamidase, and (b) utilization of niacins by nicotinate phosphoribosyltransferase and nicotinamide phosphoribosyltransferase.

Despite certain limitations, investigators continue to gainfully employ concepts rooted in steady-state kinetics in efforts to draw mechanistically relevant inferences about enzyme catalysis. By reconsidering steady-state enzyme kinetic behavior, this review develops ideas that allow one to arrive at the following new definitions: (a) V/K, the ratio of the maximal initial velocity divided by the Michaelis-Menten constant, is the apparent rate constant for the capture of substrate into enzyme complexes that are destined to yield product(s) at some later point in time; (b) the maximal velocity V is the apparent rate constant for the release of substrate from captured complexes in the form of free product(s); and (c) the Michaelis-Menten constant K is the ratio of the apparent rate constants for release and capture. The physiologic significance of V/K is also explored to illuminate aspects of antibiotic resistance, the concept of "perfection" in enzyme catalysis, and catalytic proficiency. The conceptual basis of congruent thermodynamic cycles is also considered in an attempt to achieve an unambiguous way for comparing an enzyme-catalyzed reaction with its uncatalyzed reference reaction. Such efforts promise a deeper understanding of the origins of catalytic power, as it relates to stabilization of the reactant ground state, stabilization of the transition state, and reciprocal stabilizations of ground and transition states.

The MutT enzyme prevents errors in DNA replication by hydrolyzing mutagenic nucleotide substrates such as 8-oxo-dGTP. It does so by catalyzing nucleophilic attack at the electron rich P beta of nucleoside triphosphates. Members of this small mechanistic class of enzymes require two divalent cations per active site for activity--one coordinated by the enzyme and the other by the enzyme-bound NTP--and show low catalytic powers of 10(7)- to 10(9)-fold. The first structure of an enzyme of this class, obtained by NMR methods in solution, shows MutT to be a compact globular protein with an alpha + beta-fold. The binding of the essential divalent cation activator Mg2+ and the substrate analog Mg(2+)-AMPCPP to the MutT enzyme to form the quaternary E-Mg(2+)-AMPCPP-Mg2+ complex does not alter the global fold of the enzyme but produces localized small conformational changes at or near the metal and substrate binding sites. The adenine-ribose moiety binds in a hydrophobic cleft near 3-strands of a mixed beta-sheet, with the 6-NH2 group of the purine ring approaching the -NH2 side chain of Asn-119. With a 6-keto group, GTP would interact more favorably with Asn-119, consistent with the substrate preference of MutT for guanine over adenine nucleotides. The enzyme-bound metal is coordinated by three conserved Glu residues (Glu-56, Glu-57, and Glu-98), the backbone carbonyl of a conserved Gly residue (Gly-38), and by two water ligands. The metal-triphosphate moiety of the metal-AMPCPP complex binds in the second coordination sphere of the enzyme-bound divalent cation. One of the water ligands of the enzyme-bound metal ion is well positioned to attack P beta with inversion and to be deprotonated or oriented by Glu-53, which in turn may be oriented by Arg-52. Lys-39 is positioned to interact electrostatically with the alpha-phosphoryl group and thereby to facilitate the departure of the NMP-leaving group. Quantitatively, the 10(9)-fold rate acceleration produced by the MutT enzyme may be ascribed to catalysis by approximation and polarization of the attacking water by the enzyme-bound metal ion (> or = 10(5)-fold), activation of the NMP leaving group by Lys-39 (10-fold), charge neutralization at P beta by the nucleotide-bound divalent cation (> or = 10-fold), and orientation and/or deprotonation of the attacking water by Glu-53 (> or = 10(2)-fold). This reaction mechanism, derived from the solution structure of the quaternary MutT complex, is both qualitatively and quantitatively consistent with the results of mutagenesis studies and may well be applicable to other enzymes that catalyze nucleophilic substitution at the electron-rich P beta of NTP substrates.

The catalytic mechanisms of adenylate kinase, guanylate kinase, uridylate kinase, and cytidylate kinase are reviewed in terms of kinetic and structural information that has been obtained in recent years. All four kinases share a highly related tertiary structure, characterized by a central five-stranded parallel beta-sheet with helices on both sides, as well as the three regions designated as the CORE, NMPbind, and LID domains. The catalytic mechanism continues to be refined to higher levels of resolution by iterative structure-function studies, and the strengths and limitations of site-directed mutagenesis are well illustrated in the case of adenylate kinase. The identity and roles of active site residues now appear to be resolved, and this review describes how specific site substitutions with unnatural amino acid side-chains have proven to be a major advance. Likewise, there is mounting evidence that phosphoryl transfer occurs by an associative transition state, based on (a) the stereochemical course of phosphoryl transfer, (b) geometric considerations, (c) examination of likely electronic distributions, (d) the orientation of the phosphoryl acceptor relative to the phosphoryl being transferred, (e) the most likely role of magnesium ion, (f) the lack of restricted access of solvent water, and (g) the results of oxygen-18 kinetic isotope. effect experiments.

The metabolite glutathione fulfills many important and chemically complex roles in protecting cellular components from the deleterious effects of toxic species. GSH combines with hydroxyl radical, peroxynitrite, and hydroperoxides, as well as reactive electrophiles, including activated phosphoramide mustard. This thiol-containing reductant also maintains so-called thiol-enzymes in their catalytically active form, and maintains vitamins C and E in their biologically active forms. The key step in glutathione synthesis, namely the ATP-dependent synthesis of gamma-glutamylcysteine, is the topic of this review. Details are presented on (a) the enzyme's purification and protein chemistry, (b) the successful cDNA cloning, and characterization of the genes responsible for the biosynthesis of this enzyme. After considering aspects of the role of overexpression of this synthetase in terms of cancer chemotherapy, attention is focused on post-translational regulation. The remainder of the review deals with the catalytic mechanism (including substrate specificity, reactions catalyzed, steady-state kinetics, and chemical mechanism) as well as the inhibition of the enzyme (via feedback inhibition, reaction with S-alkyl homocysteine sulfoximine inhibitors, the clinical use of buthionine sulfoximine with cancer patients, and inactivation by cystamine, chloroketones, and various nitric oxide donors).

Under the narrow range of experimental conditions, and at a temperature of approximately 25 degrees, the following data were obtained. 1. The equilibrium constant of peroxidase and hydrogen peroxide has a minimum value of 2 x 10(-8). 2. The velocity constant for the formation of peroxidase-H2O2 Complex I is 1.2 x 10(7) liter mole-1 sec.-1, +/- 0.4 x 10(7). 3. The velocity constant for the reversible breakdown of peroxidase-H2O2 Complex I is a negligible factor in the enzyme-substrate kinetics and is calculated to be less than 0.2 sec.-1. 4. The velocity constant, k3, for the enzymatic breakdown of peroxidase-H2O2 Complex I varies from nearly zero to higher than 5 sec.-1, depending upon the acceptor and its concentration. The quotient of k3 and the leucomalachite green concentration is 3.0 x 10(4) liter mole-1 sec.-1. For ascorbic acid this has a value of 1.8 x 10(5) liter mole-1 sec.-1. 5. For a particular acceptor concentration, k3 is determined solely from the enzyme-substrate kinetics and is found to be 4.2 sec.-1. 6. For the same conditions, k3 is determined from a simple relationship derived from mathematical solutions of the Michaelis theory and is found to be 5.2 sec.-1. 7. For the same conditions, k3 is determined from the over-all enzyme action and is found to be 5.1 sec.-1. 8. The Michaelis constant determined from kinetic data alone is found to be 0.44 x 10(-6). 9. The Michaelis constant determined from steady state measurements is found to be 0.41 x 10(-6). 10. The Michaelis constant determined from measurement of the overall enzyme reaction is found to be 0.50 x 10(-6). 11. The kinetics of the enzyme-substrate compound closely agree with mathematical solutions of an extension of the Michaelis theory obtained for experimental values of concentrations and reaction velocity constants. 12. The adequacy of the criteria by which experiment and theory were correlated has been examined critically and the mathematical solutions have been found to be sensitive to variations in the experimental conditions. 13. The critical features of the enzyme-substrate kinetics are Pmax, and curve shape, rather than t1/2. t1/2 serves as a simple measure of dx/dt. 14. A second order combination of enzyme and substrate to form the enzyme-substrate compound, followed by a first order breakdown of the compound, describes the activity of peroxidase for a particular acceptor concentration. 15. The kinetic data indicate a bimolecular combination of acceptor and enzyme-substrate compound.