Substrate and metal ion promiscuity in mannosylglycerate synthase

The enzymatic transfer of the sugar mannose from activated sugar donors is central to the synthesis of a wide range of biologically significant polysaccharides and glycoconjugates. In addition to their importance in cellular biology, mannosyltransferases also provide model systems with which to study catalytic mechanisms of glycosyl transfer. Mannosylglycerate synthase (MGS) catalyzes the synthesis of α-mannosyl-D-glycerate using GDP-mannose as the preferred donor species, a reaction that occurs with a net retention of anomeric configuration. Past work has shown that the Rhodothermus marinus MGS, classified as a GT78 glycosyltransferase, displays a GT-A fold and performs catalysis in a metal ion-dependent manner. MGS shows very unusual metal ion dependences with Mg(2+) and Ca(2+) and, to a lesser extent, Mn(2+), Ni(2+), and Co(2+), thus facilitating catalysis. Here, we probe these dependences through kinetic and calorimetric analyses of wild-type and site-directed variants of the enzyme. Mutation of residues that interact with the guanine base of GDP are correlated with a higher k(cat) value, whereas substitution of His-217, a key component of the metal coordination site, results in a change in metal specificity to Mn(2+). Structural analyses of MGS complexes not only provide insight into metal coordination but also how lactate can function as an alternative acceptor to glycerate. These studies highlight the role of flexible loops in the active center and the subsequent coordination of the divalent metal ion as key factors in MGS catalysis and metal ion dependence. Furthermore, Tyr-220, located on a flexible loop whose conformation is likely influenced by metal binding, also plays a critical role in substrate binding.     

Mechanistic insights into the retaining glucosyl-3-phosphoglycerate synthase from mycobacteria

Considerable progress has been made in recent years in our understanding of the structural basis of glycosyl transfer. Yet the nature and relevance of the conformational changes associated with substrate recognition and catalysis remain poorly understood. We have focused on the glucosyl-3-phosphoglycerate synthase (GpgS), a "retaining" enzyme, that initiates the biosynthetic pathway of methylglucose lipopolysaccharides in mycobacteria. Evidence is provided that GpgS displays an unusually broad metal ion specificity for a GT-A enzyme, with Mg(2+), Mn(2+), Ca(2+), Co(2+), and Fe(2+) assisting catalysis. In the crystal structure of the apo-form of GpgS, we have observed that a flexible loop adopts a double conformation L(A) and L(I) in the active site of both monomers of the protein dimer. Notably, the L(A) loop geometry corresponds to an active conformation and is conserved in two other relevant states of the enzyme, namely the GpgS·metal·nucleotide sugar donor and the GpgS·metal·nucleotide·acceptor-bound complexes, indicating that GpgS is intrinsically in a catalytically active conformation. The crystal structure of GpgS in the presence of Mn(2+)·UDP·phosphoglyceric acid revealed an alternate conformation for the nucleotide sugar β-phosphate, which likely occurs upon sugar transfer. Structural, biochemical, and biophysical data point to a crucial role of the β-phosphate in donor and acceptor substrate binding and catalysis. Altogether, our experimental data suggest a model wherein the catalytic site is essentially preformed, with a few conformational changes of lateral chain residues as the protein proceeds along the catalytic cycle. This model of action may be applicable to a broad range of GT-A glycosyltransferases.     

Slow binding of metal ions to pigeon liver malic enzyme: a general case

Pigeon liver malic enzyme was inhibited by lutetium ion through a slow-binding process, which resulted in a concave down tracing of the enzyme activity assay. The fast initial rates were independent of lutetium ion concentration, while the slow steady-state rates decreased with increasing Lu(3+) concentration. The observed rate constant for the transition from initial rate to steady-state rate, k(obs), exhibited saturation kinetics as a function of Lu(3+) concentration, suggesting the involvement of an isomerization process between two enzyme forms (R-form and T-form). The binding affinity of Lu(3+) to the R-form is weaker (K(d,Lu) = 14 microM) than that of Mn(2+) (K(m,Mn) = 1.89 microM); however, Lu(3+) has much tighter binding affinity with the T-form ( = 0.83 microM). Lu(3+) was shown to be a competitive inhibitor with respect to Mn(2+), which suggests that Lu(3+) and Mn(2+) are competing for the same metal binding site of the enzyme. These observations are in accordance with the available crystal structure information, which shows a distorted active site region of the Lu(3+)-containing enzyme. Other divalent cations, i.e., Fe(2+), Cu(2+), or Zn(2+), also act as time-dependent slow inhibitors for malic enzyme. The dynamic quenching constants of the intrinsic fluorescence for the metal-free and Lu(3+)-containing enzymes are quite different, indicating the conformational differences between the two enzyme forms. The secondary structure of these two enzyme forms, on the other hand, was not changed. The above results indicated that replacement of the catalytically essential Mn(2+) by other metal ions leads to a slow conformational change of the enzyme and consequently alters the geometry of the active site. The transformed enzyme conformation, however, is unfavorable for catalysis. Both the chemical nature of the metal ion and its correct coordination in the active site are essential for catalysis.     

Metal ions binding to NAD-glycohydrolase from the venom of Agkistrodon acutus: regulation of multicatalytic activity

AA-NADase from Agkistrodon acutus venom is a unique multicatalytic enzyme with both NADase and AT(D)Pase activities. Among all identified NADases, only AA-NADase contains Cu(2+) ions that are essential for its multicatalytic activity. In this study, the interactions between divalent metal ions and AA-NADase and the effects of metal ions on its structure and activity have been investigated by equilibrium dialysis, isothermal titration calorimetry, fluorescence, circular dichroism, dynamic light scattering and HPLC. The results show that AA-NADase has two classes of Cu(2+) binding sites, one activator site with high affinity and approximately six inhibitor sites with low affinity. Cu(2+) ions function as a switch for its NADase activity. In addition, AA-NADase has one Mn(2+) binding site, one Zn(2+) binding site, one strong and two weak Co(2+) binding sites, and two strong and six weak Ni(2+) binding sites. Metal ion binding affinities follow the trend Cu(2+) > Ni(2+) > Mn(2+) > Co(2+) > Zn(2+), which accounts for the existence of one Cu(2+) in the purified AA-NADase. Both NADase and ADPase activities of AA-NADase do not have an absolute requirement for Cu(2+), and all tested metal ions activate its NADase and ADPase activities and the activation capacity follows the trend Zn(2+) > Mn(2+) > Cu(2+) ~Co(2+) > Ni(2+). Metal ions serve as regulators for its multicatalytic activity. Although all tested metal ions have no obvious effects on the global structure of AA-NADase, Cu(2+)- and Zn(2+)-induced conformational changes around some Trp residues have been observed. Interestingly, each tested metal ion has a very similar activation of both NADase and ADPase activities, suggesting that the two different activities probably occur at the same site.     

Crystal structure of imidazole glycerol phosphate synthase: a tunnel through a (beta/alpha)8 barrel joins two active sites

BACKGROUND: Imidazole glycerol phosphate synthase catalyzes a two-step reaction of histidine biosynthesis at the bifurcation point with the purine de novo pathway. The enzyme is a new example of intermediate channeling by glutamine amidotransferases in which ammonia generated by hydrolysis of glutamine is channeled to a second active site where it acts as a nucleophile. In this case, ammonia reacts in a cyclase domain to produce imidazole glycerol phosphate and an intermediate of purine biosynthesis. The enzyme is also a potential target for drug and herbicide development since the histidine pathway does not occur in mammals. RESULTS: The 2.1 A crystal structure of imidazole glycerol phosphate synthase from yeast reveals extensive interaction of the glutaminase and cyclase catalytic domains. At the domain interface, the glutaminase active site points into the bottom of the (beta/alpha)(8) barrel of the cyclase domain. An ammonia tunnel through the (beta/alpha)(8) barrel connects the glutaminase docking site at the bottom to the cyclase active site at the top. A conserved "gate" of four charged residues controls access to the tunnel. CONCLUSIONS: This is the first structure in which all the components of the ubiquitous (beta/alpha)(8) barrel fold, top, bottom, and interior, take part in enzymatic function. Intimate contacts between the barrel domain and the glutaminase active site appear to be poised for crosstalk between catalytic centers in response to substrate binding at the cyclase active site. The structure provides a number of potential sites for inhibitor development in the active sites and in a conserved interdomain cavity.     

Heparan/chondroitin sulfate biosynthesis. Structure and mechanism of human glucuronyltransferase I

Human beta1,3-glucuronyltransferase I (GlcAT-I) is a central enzyme in the initial steps of proteoglycan synthesis. GlcAT-I transfers a glucuronic acid moiety from the uridine diphosphate-glucuronic acid (UDP-GlcUA) to the common linkage region trisaccharide Gal beta 1-3Gal beta 1-4Xyl covalently bound to a Ser residue at the glycosaminylglycan attachment site of proteoglycans. We have now determined the crystal structure of GlcAT-1 at 2.3 A in the presence of the donor substrate product UDP, the catalytic Mn(2+) ion, and the acceptor substrate analog Gal beta 1-3Gal beta 1-4Xyl. The enzyme is a alpha/beta protein with two subdomains that constitute the donor and acceptor substrate binding site. The active site residues lie in a cleft extending across both subdomains in which the trisaccharide molecule is oriented perpendicular to the UDP. Residues Glu(227), Asp(252), and Glu(281) dictate the binding orientation of the terminal Gal-2 moiety. Residue Glu(281) is in position to function as a catalytic base by deprotonating the incoming 3-hydroxyl group of the acceptor. The conserved DXD motif (Asp(194), Asp(195), Asp(196)) has direct interaction with the ribose of the UDP molecule as well as with the Mn(2+) ion. The key residues involved in substrate binding and catalysis are conserved in the glucuronyltransferase family as well as other glycosyltransferases.     

Kinetic and chemical mechanisms of homocitrate synthase from Thermus thermophilus

The homocitrate synthase from Thermus thermophilus (TtHCS) is a metal-activated enzyme with either Mg(2+) or Mn(2+) capable of serving as the divalent cation. The enzyme exhibits a sequential kinetic mechanism. The mechanism is steady state ordered with α-ketoglutarate (α-Kg) binding prior to acetyl-CoA (AcCoA) with Mn(2+), whereas it is steady state random with Mg(2+), suggesting a difference in the competence of the E·Mn·α-Kg·AcCoA and E·Mg·α-Kg·AcCoA complexes. The mechanism is supported by product and dead-end inhibition studies. The primary isotope effect obtained with deuterioacetylCoA (AcCoA-d(3)) in the presence of Mg(2+) is unity (value 1.0) at low concentrations of AcCoA, whereas it is 2 at high concentrations of AcCoA. Data suggest the presence of a slow conformational change induced by binding of AcCoA that accompanies deprotonation of the methyl group of AcCoA. The solvent kinetic deuterium isotope effect is also unity at low AcCoA, but is 1.7 at high AcCoA, consistent with the proposed slow conformational change. The maximum rate is pH independent with either Mg(2+) or Mn(2+) as the divalent metal ion, whereas V/K(α-Kg) (with Mn(2+)) decreases at low and high pH giving pK values of about 6.5 and 8.0. Lysine is a competitive inhibitor that binds to the active site of TtHCS, and shares some of the same binding determinants as α-Kg. Lysine binding exhibits negative cooperativity, indicating cross-talk between the two monomers of the TtHCS dimer. Data are discussed in terms of the overall mechanism of TtHCS.     

Studies on the metal binding sites in the catalytic domain of beta1,4-galactosyltransferase

The catalytic domain of bovine beta1,4-galactosyltransferase (beta4Gal-T1) has been shown to have two metal binding sites, each with a distinct binding affinity. Site I binds Mn(2+) with high affinity and does not bind Ca(2+), whereas site II binds a variety of metal ions, including Ca(2+). The catalytic region of beta4Gal-T1 has DXD motifs, associated with metal binding in glycosyltransferases, in two separate sequences: D(242)YDYNCFVFSDVD(254) (region I) and W(312)GWGGEDDD(320) (region II). Recently, the crystal structure of beta4Gal-T1 bound with UDP, Mn(2+), and alpha-lactalbumin was determined in our laboratory. It shows that in the primary metal binding site of beta4Gal-T1, the Mn(2+) ion, is coordinated to five ligands, two supplied by the phosphates of the sugar nucleotide and the other three by Asp254, His347, and Met344. The residue Asp254 in the D(252)VD(254) sequence in region I is the only residue that is coordinated to the Mn(2+) ion. Region II forms a loop structure and contains the E(317)DDD(320) sequence in which residues Asp318 and Asp319 are directly involved in GlcNAc binding. This study, using site-directed mutagenesis, kinetic, and binding affinity analysis, shows that Asp254 and His347 are strong metal ligands, whereas Met344, which coordinates less strongly, can be substituted by alanine or glutamine. Specifically, substitution of Met344 to Gln has a less severe effect on the catalysis driven by Co(2+). Glu317 and Asp320 mutants, when partially activated by Mn(2+) binding to the primary site, can be further activated by Co(2+) or inhibited by Ca(2+), an effect that is the opposite of what is observed with the wild-type enzyme.     

Atomic structure of salutaridine reductase from the opium poppy (Papaver somniferum)

The opium poppy (Papaver somniferum L.) is one of the oldest known medicinal plants. In the biosynthetic pathway for morphine and codeine, salutaridine is reduced to salutaridinol by salutaridine reductase (SalR; EC 1.1.1.248) using NADPH as coenzyme. Here, we report the atomic structure of SalR to a resolution of ∼1.9 Å in the presence of NADPH. The core structure is highly homologous to other members of the short chain dehydrogenase/reductase family. The major difference is that the nicotinamide moiety and the substrate-binding pocket are covered by a loop (residues 265–279), on top of which lies a large “flap”-like domain (residues 105–140). This configuration appears to be a combination of the two common structural themes found in other members of the short chain dehydrogenase/reductase family. Previous modeling studies suggested that substrate inhibition is due to mutually exclusive productive and nonproductive modes of substrate binding in the active site. This model was tested via site-directed mutagenesis, and a number of these mutations abrogated substrate inhibition. However, the atomic structure of SalR shows that these mutated residues are instead distributed over a wide area of the enzyme, and many are not in the active site. To explain how residues distal to the active site might affect catalysis, a model is presented whereby SalR may undergo significant conformational changes during catalytic turnover.     

Saturation mutagenesis, complement selection, and steady-state kinetic studies illuminate the roles of invariant residues in active site loop I of the hypoxanthine phosphoribosyltransferase from Trypanosoma cruzi

Hypoxanthine phosphoribosyltransferases (HPRTs) are potential drug targets in the treatment of diseases caused by parasites. Also, defects in the human HPRT can result in gouty arthritis or Lesch-Nyhan syndrome. Active site loop I of HPRTs has been implicated in interactions between enzyme subunits that can influence the relative efficiencies of forward and reverse reactions, but the functional roles for invariant loop I residues (analogous with human Leu67 and Gly69) are poorly understood. Herein, saturation mutagenesis, complement selection, and steady-state kinetics were used to investigate the functional roles for Leu67 and Gly69. Seventy clones from a library of mutants were sequenced and more than 30 different mutations, or combinations of mutations, were identified. Several recombinant HPRTs with mutations at positions 67 and/or 69 supported the growth of a bacterial auxotroph on selective media, but only two of the mutants (L67M and G69S) could be recovered in the soluble fraction from bacteria induced to over-express the enzyme. The results of steady-state kinetic studies for L67M are consistent with the side chain of this residue participating in hydrophobic interactions between dimer subunits that are important for the proper positioning of main chain atoms that influence enzyme chemistry and the binding of PRPP, PPi, and hypoxanthine. The results for mutations at position 69 are consistent with only hydrogen or a small polar side chain being tolerated at this site. Kinetic studies of G69S suggest that side chains of residues at position 69 that project into the active site likely interfere with the binding of PRPP and PPi, as well as the positioning of a metal ion that indirectly influences the binding of purine bases and purine moieties of nucleotide substrates.     

Unraveling the substrate-metal binding site of ferrochelatase: an X-ray absorption spectroscopic study

Ferrochelatase (EC 4.99.1.1), the terminal enzyme of the heme biosynthetic pathway, catalyzes the insertion of ferrous iron into the protoporphyrin IX ring. Ferrochelatases can be arbitrarily divided into two broad categories: those with and those without a [2Fe-2S] center. In this work we have used X-ray absorption spectroscopy to investigate the metal ion binding sites of murine and Saccharomyces cerevisiae (yeast) ferrochelatases, which are representatives of the former and latter categories, respectively. Co(2+) and Zn(2+) complexes of both enzymes were studied, but the Fe(2+) complex was only studied for yeast ferrochelatase because the [2Fe-2S] center of the murine enzyme interferes with the analysis. Co(2+) and Zn(2+) binding to site-directed mutants of the murine enzyme were also studied, in which the highly conserved and potentially metal-coordinating residues H207 and Y220 were substituted by residues that should not coordinate metal (i.e., H207N, H207A, and Y220F). Our experiments indicate four-coordinate zinc with Zn(N/O)(3)(S/Cl)(1) coordination for the yeast and Zn(N/O)(2)(S/Cl)(2) coordination for the wild-type murine enzyme. In contrast to zinc, a six-coordinate site for Co(2+) coordinated with oxygen or nitrogen was present in both the yeast and murine (wild-type and mutated) enzymes, with evidence of two histidine ligands in both. Like Co(2+), Fe(2+) bound to yeast ferrochelatase was coordinated by approximately six oxygen or nitrogen ligands, again with evidence of two histidine ligands. For the murine enzyme, mutation of both H207 and Y220 significantly changed the spectra, indicating a likely role for these residues in metal ion substrate binding. This is in marked disagreement with the conclusions from X-ray crystallographic studies of the human enzyme, and possible reasons for this are discussed.     

Characterization of the deoxynucleotide triphosphate triphosphohydrolase (dNTPase) activity of the EF1143 protein from Enterococcus faecalis and crystal structure of the activator-substrate complex

The EF1143 protein from Enterococcus faecalis is a distant homolog of deoxynucleotide triphosphate triphosphohydrolases (dNTPases) from Escherichia coli and Thermus thermophilus. These dNTPases are important components in the regulation of the dNTP pool in bacteria. Biochemical assays of the EF1143 dNTPase activity demonstrated nonspecific hydrolysis of all canonical dNTPs in the presence of Mn(2+). In contrast, with Mg(2+) hydrolysis required the presence of dGTP as an effector, activating the degradation of dATP and dCTP with dGTP also being consumed in the reaction with dATP. The crystal structure of EF1143 and dynamic light scattering measurements in solution revealed a tetrameric oligomer as the most probable biologically active unit. The tetramer contains four dGTP specific allosteric regulatory sites and four active sites. Examination of the active site with the dATP substrate suggests an in-line nucleophilic attack on the α-phosphate center as a possible mechanism of the hydrolysis and two highly conserved residues, His-129 and Glu-122, as an acid-base catalytic dyad. Structural differences between EF1143 apo and holo forms revealed mobility of the α3 helix that can regulate the size of the active site binding pocket and could be stabilized in the open conformation upon formation of the tetramer and dGTP effector binding.     

Vascular Bioactivation of Nitroglycerin by Aldehyde Dehydrogenase-2: REACTION INTERMEDIATES REVEALED BY CRYSTALLOGRAPHY AND MASS SPECTROMETRY*

Aldehyde dehydrogenase-2 (ALDH2) catalyzes the bioactivation of nitroglycerin (glyceryl trinitrate, GTN) in blood vessels, resulting in vasodilation by nitric oxide (NO) or a related species. Because the mechanism of this reaction is still unclear we determined the three-dimensional structures of wild-type (WT) ALDH2 and of a triple mutant of the protein that exhibits low denitration activity (E268Q/C301S/C303S) in complex with GTN. The structure of the triple mutant showed that GTN binds to the active site via polar contacts to the oxyanion hole and to residues 268 and 301 as well as by van der Waals interactions to hydrophobic residues of the catalytic pocket. The structure of the GTN-soaked wild-type protein revealed a thionitrate adduct to Cys-302 as the first reaction intermediate, which was also found by mass spectrometry (MS) experiments. In addition, the MS data identified sulfinic acid as the irreversibly inactivated enzyme species. Assuming that the structures of the triple mutant and wild-type ALDH2 reflect binding of GTN to the catalytic site and the first reaction step, respectively, superposition of the two structures indicates that denitration of GTN is initiated by nucleophilic attack of Cys-302 at one of the terminal nitrate groups, resulting in formation of the observed thionitrate intermediate and release of 1,2-glyceryl dinitrate. Our results shed light on the molecular mechanism of the GTN denitration reaction and provide useful information on the structural requirements for high affinity binding of organic nitrates to the catalytic site of ALDH2.     

Structural analyses of a purine biosynthetic enzyme from Mycobacterium tuberculosis reveal a novel bound nucleotide

Enzymes of the de novo purine biosynthetic pathway have been identified as essential for the growth and survival of Mycobacterium tuberculosis and thus have potential for the development of anti-tuberculosis drugs. The final two steps of this pathway are carried out by the bifunctional enzyme 5-aminoimidazole-4-carboxamide ribonucleotide transformylase/inosine monophosphate cyclohydrolase (ATIC), also known as PurH. This enzyme has already been the target of anti-cancer drug development. We have determined the crystal structures of the M. tuberculosis ATIC (Rv0957) both with and without the substrate 5-aminoimidazole-4-carboxamide ribonucleotide, at resolutions of 2.5 and 2.2 Å, respectively. As for other ATIC enzymes, the protein is folded into two domains, the N-terminal domain (residues 1–212) containing the cyclohydrolase active site and the C-terminal domain (residues 222–523) containing the formyltransferase active site. An adventitiously bound nucleotide was found in the cyclohydrolase active site in both structures and was identified by NMR and mass spectral analysis as a novel 5-formyl derivative of an earlier intermediate in the biosynthetic pathway 4-carboxy-5-aminoimidazole ribonucleotide. This result and other studies suggest that this novel nucleotide is a cyclohydrolase inhibitor. The dimer formed by M. tuberculosis ATIC is different from those seen for human and avian ATICs, but it has a similar ∼50-Å separation of the two active sites of the bifunctional enzyme. Evidence in M. tuberculosis ATIC for reactivity of half-the-sites in the cyclohydrolase domains can be attributed to ligand-induced movements that propagate across the dimer interface and may be a common feature of ATIC enzymes.     

Structural Insights into the Substrate Specificity of (S)-Ureidoglycolate Amidohydrolase and Its Comparison with Allantoate Amidohydrolase

In plants, the ureide pathway is a metabolic route that converts the ring nitrogen atoms of purine into ammonia via sequential enzymatic reactions, playing an important role in nitrogen recovery. In the final step of the pathway, (S)-ureidoglycolate amidohydrolase (UAH) catalyzes the conversion of (S)-ureidoglycolate into glyoxylate and releases two molecules of ammonia as by-products. UAH is homologous in structure and sequence with allantoate amidohydrolase (AAH), an upstream enzyme in the pathway with a similar function as that of an amidase but with a different substrate. Both enzymes exhibit strict substrate specificity and catalyze reactions in a concerted manner, resulting in purine degradation. Here, we report three crystal structures of Arabidopsis thaliana UAH (bound with substrate, reaction intermediate, and product) and a structure of Escherichia coli AAH complexed with allantoate. Structural analyses of UAH revealed a distinct binding mode for each ligand in a bimetal reaction center with the active site in a closed conformation. The ligand directly participates in the coordination shell of two metal ions and is stabilized by the surrounding residues. In contrast, AAH, which exhibits a substrate-binding site similar to that of UAH, requires a larger active site due to the additional ureido group in allantoate. Structural analyses and mutagenesis revealed that both enzymes undergo an open-to-closed conformational transition in response to ligand binding and that the active-site size and the interaction environment in UAH and AAH are determinants of the substrate specificities of these two structurally homologous enzymes.     

DNA cleavage by EcoRV endonuclease: two metal ions in three metal ion binding sites

Four crystal structures of EcoRV endonuclease mutants K92A and K38A provide new insight into the mechanism of DNA bending and the structural basis for metal-dependent phosphodiester bond cleavage. The removal of a key active site positive charge in the uncleaved K92A-DNA-M(2+) substrate complex results in binding of a sodium ion in the position of the amine nitrogen, suggesting a key role for a positive charge at this position in stabilizing the sharp DNA bend prior to cleavage. By contrast, two structures of K38A cocrystallized with DNA and Mn(2+) ions in different lattice environments reveal cleaved product complexes featuring a common, novel conformation of the scissile phosphate group as compared to all previous EcoRV structures. In these structures, the released 5'-phosphate and 3'-OH groups remain in close juxtaposition with each other and with two Mn(2+) ions that bridge the conserved active site carboxylates. The scissile phosphates are found midway between their positions in the prereactive substrate and postreactive product complexes of the wild-type enzyme. Mn(2+) ions occupy two of the three sites previously described in the prereactive complexes and are plausibly positioned to generate the nucleophilic hydroxide ion, to compensate for the incipient additional negative charge in the transition state, and to ionize a second water for protonation of the 3'-oxyanion. Reconciliation of these findings with earlier X-ray and fluorescence studies suggests a novel mechanism in which a single initially bound metal ion in a third distinct site undergoes a shift in position together with movement of the scissile phosphate deeper into the active site cleft. This reconfigures the local environment to permit binding of the second metal ion followed by movement toward the pentacovalent transition state. The new mechanism suggested here embodies key features of previously proposed two- and three-metal catalytic models, and offers a view of the stereochemical pathway that integrates much of the copious structural and functional data that are available from exhaustive studies in many laboratories.     

Structure of imidazole glycerol phosphate synthase from Thermus thermophilus HB8: open-closed conformational change and ammonia tunneling

Imidazole glycerol phosphate synthase (IGPs) catalyzes the fifth step in the histidine biosynthetic pathway located at the branch point to de novo purine biosynthesis. IGPs is a multienzyme comprising glutaminase and synthase subunits. The glutaminase activity, which hydrolyzes glutamine to give ammonia, is coupled with substrate binding to the synthase subunit. The three-dimensional structure of the IGPs from Thermus thermophilus HB8 has been determined at 2.3 A resolution, and compared with the previously determined structures for the yeast and Thermotoga maritima enzymes. The structure of each subunit is similar to that of the corresponding domain in the yeast enzyme or subunit in the T. maritima enzyme. However, the overall structure is significantly different from the yeast and T. maritima enzymes, indicating that IGPs may change the relative orientation between the two subunits and close the glutaminase site upon glutamine binding. The putative ammonia tunnel, which carries nascent ammonia from glutaminase to the synthase site, has a closed gate comprising a cyclic salt bridge formed by four charged residues of the synthase subunit. The side chain of Lys100 in the cyclic salt bridge might change its side chain direction to form new interactions with the main chain carbonyl group of glutamine from the synthase subunit and the hydoxyl group of tyrosine from the glutaminase subunit, resulting in the opening of the gate for ammonia transfer.     

Crystal structure of N-succinylarginine dihydrolase AstB, bound to substrate and product, an enzyme from the arginine catabolic pathway of Escherichia coli

The ammonia-producing arginine succinyltransferase pathway is the major pathway in Escherichia coli and related bacteria for arginine catabolism as a sole nitrogen source. This pathway consists of five steps, each catalyzed by a distinct enzyme. Here we report the crystal structure of N-succinylarginine dihydrolase AstB, the second enzyme of the arginine succinyltransferase pathway, providing the first structural insight into enzymes from this pathway. The enzyme exhibits a pseudo 5-fold symmetric alpha/beta propeller fold of circularly arranged betabetaalphabeta modules enclosing the active site. The crystal structure indicates clearly that this enzyme belongs to the amidinotransferase (AT) superfamily and that the active site contains a Cys-His-Glu triad characteristic of the AT superfamily. Structures of the complexes of AstB with the reaction product and a C365S mutant with bound the N-succinylarginine substrate suggest a catalytic mechanism that consists of two cycles of hydrolysis and ammonia release, with each cycle utilizing a mechanism similar to that proposed for arginine deiminases. Like other members of the AT superfamily of enzymes, AstB possesses a flexible loop that is disordered in the absence of substrate and assumes an ordered conformation upon substrate binding, shielding the ligand from the bulk solvent, thereby controlling substrate access and product release.     

Substrate binding to fluorescent labeled wild type, Lys213Arg, and HIS233Gln Saccharomyces cerevisiae phosphoenolpyruvate carboxykinases

Saccharomyces cerevisiae phosphoenolpyruvate (PEP) carboxykinase is a key enzyme of the gluconeogenic pathway and catalyzes the decarboxylation of oxaloacetate and transfer of the gamma-phosphoryl group of ATP to yield PEP, ADP, and CO(2) in the presence of a divalent metal ion. Previous experiments have shown that mutation of amino acid residues at metal site 1 decrease the steady-state affinity of the enzyme for PEP, suggesting interaction of PEP with the metal ion [Biochemistry 41 (2002) 12763]. To more completely understand this enzyme interactions with substrate ligands, we have prepared the phosphopyridoxyl (P-pyridoxyl)-derivatives of wild type, Lys213Arg, and His233Gln S. cerevisiae PEP carboxykinase and used the changes in the fluorescence probe to determine the dissociation equilibrium constants of PEP, ATPMn(2-), and ADPMn(1-) from the corresponding derivatized enzyme-Mn(2+) complexes. Homology modeling of P-pyridoxyl-PEP carboxykinase and P-pyridoxyl-PEP carboxykinase-substrate complexes agree with experimental evidence indicating that the P-pyridoxyl group does not interfere with substrate binding. ATPMn(2-) binding is 0.8kcalmol(-1) more favorable than ADPMn(1-) binding to wild type P-pyridoxyl-enzyme. The thermodynamic data obtained in this work indicate that PEP binding is 2.3kcalmol(-1) and 3.2kcalmol(-1) less favorable for the Lys213Arg and His233Gln mutant P-pyridoxyl-PEP carboxykinases than for the wild type P-pyridoxyl-enzyme, respectively. The possible relevance of N and O ligands for Mn(2+) in relation to PEP binding and catalysis is discussed.     

Structure and function of APH(4)-Ia, a hygromycin B resistance enzyme

The aminoglycoside phosphotransferase (APH) APH(4)-Ia is one of two enzymes responsible for bacterial resistance to the atypical aminoglycoside antibiotic hygromycin B (hygB). The crystal structure of APH(4)-Ia enzyme was solved in complex with hygB at 1.95 Å resolution. The APH(4)-Ia structure adapts a general two-lobe architecture shared by other APH enzymes and eukaryotic kinases, with the active site located at the interdomain cavity. The enzyme forms an extended hydrogen bond network with hygB primarily through polar and acidic side chain groups. Individual alanine substitutions of seven residues involved in hygB binding did not have significant effect on APH(4)-Ia enzymatic activity, indicating that the binding affinity is spread across a distributed network. hygB appeared as the only substrate recognized by APH(4)-Ia among the panel of 14 aminoglycoside compounds. Analysis of the active site architecture and the interaction with the hygB molecule demonstrated several unique features supporting such restricted substrate specificity. Primarily the APH(4)-Ia substrate-binding site contains a cluster of hydrophobic residues that provides a complementary surface to the twisted structure of the substrate. Similar to APH(2″) enzymes, the APH(4)-Ia is able to utilize either ATP or GTP for phosphoryl transfer. The defined structural features of APH(4)-Ia interactions with hygB and the promiscuity in regard to ATP or GTP binding could be exploited for the design of novel aminoglycoside antibiotics or inhibitors of this enzyme.