Identification of a Bifunctional UDP-4-keto-pentose/UDP-xylose Synthase in the Plant Pathogenic Bacterium Ralstonia solanacearum Strain GMI1000, a Distinct Member of the 4,6-Dehydratase and Decarboxylase Family

The UDP-sugar interconverting enzymes involved in UDP-GlcA metabolism are well described in eukaryotes but less is known in prokaryotes. Here we identify and characterize a gene (RsU4kpxs) from Ralstonia solanacearum str. GMI1000, which encodes a dual function enzyme not previously described. One activity is to decarboxylate UDP-glucuronic acid to UDP-β-l-threo-pentopyranosyl-4″-ulose in the presence of NAD⁺. The second activity converts UDP-β-l-threo-pentopyranosyl-4″-ulose and NADH to UDP-xylose and NAD⁺, albeit at a lower rate. Our data also suggest that following decarboxylation, there is stereospecific protonation at the C5 pro-R position. The identification of the R. solanacearum enzyme enables us to propose that the ancestral enzyme of UDP-xylose synthase and UDP-apiose/UDP-xylose synthase was diverged to two distinct enzymatic activities in early bacteria. This separation gave rise to the current UDP-xylose synthase in animal, fungus, and plant as well as to the plant Uaxs and bacterial ArnA and U4kpxs homologs.     

Introduction to the Thematic Minireview Series on Radical S-Adenosylmethionine (SAM) Enzymes

In the early days, radical enzyme reactions that use S-adenosylmethionine (SAM) coordinated to an Fe-S cluster, which Perry Frey described as a “poor man''s coenzyme B₁₂,” were believed to be relatively rare chemical curiosities. Today, bioinformatics analyses have revealed the wide prevalence and sheer numbers of radical SAM enzymes, conferring superfamily status. In this thematic minireview series, the JBC presents six articles on radical SAM enzymes that accomplish wide-ranging chemical transformations. We learn that despite the diversity of the reactions catalyzed, family members share some common structural and mechanistic themes. Still in its infancy, continued explorations promise to be fertile grounds for discoveries that will undoubtedly further broaden our understanding of the catalytic repertoire and deepen our understanding of the chemical strategies used by radical SAM enzymes.     

Genome-wide analysis of the UDP-glucose dehydrogenase gene family in Arabidopsis, a key enzyme for matrix polysaccharides in cell walls

Arabidopsis cell walls contain large amounts of pectins and hemicelluloses, which are predominantly synthesized via the common precursor UDP-glucuronic acid. The major enzyme for the formation of this nucleotide-sugar is UDP-glucose dehydrogenase, catalysing the irreversible oxidation of UDP-glucose into UDP-glucuronic acid. Four functional gene family members and one pseudogene are present in the Arabidopsis genome, and they show distinct tissue-specific expression patterns during plant development. The analyses of reporter gene lines indicate gene expression of UDP-glucose dehydrogenases in growing tissues. The biochemical characterization of the different isoforms shows equal affinities for the cofactor NAD(+) ( approximately 40 microM) but variable affinities for the substrate UDP-glucose (120-335 microM) and different catalytic constants, suggesting a regulatory role for the different isoforms in carbon partitioning between cell wall formation and sucrose synthesis as the second major UDP-glucose-consuming pathway. UDP-glucose dehydrogenase is feedback inhibited by UDP-xylose. The relatively (compared with a soybean UDP-glucose dehydrogenase) low affinity of the enzymes for the substrate UDP-glucose is paralleled by the weak inhibition of the enzymes by UDP-xylose. The four Arabidopsis UDP-glucose dehydrogenase isoforms oxidize only UDP-glucose as a substrate. Nucleotide-sugars, which are converted by similar enzymes in bacteria, are not accepted as substrates for the Arabidopsis enzymes.     

The regulation of synthesis of mitochondrial enzymes in regreening and division-synchronized Euglena cultures

The effect of light and carbon nutrition on the synthesis of citrate synthase (EC 4.1.3.7) and malate dehydrogenase (EC 1.1.1.37) in dark-grown resting (carbon deficient) and in phototrophic division-synchronized cultures of Euglena gracilis Klebs strain z were investigated. Exposure of dark-grown Euglena to white or red light produced a transient increase in the specific activities of citrate synthase and malate dehydrogenase but blue light (of equal energy) was ineffective. Citrate-synthase activity increased at the end of the light phase and in early dark phase in phototrophic cultures division-synchronized by a regime of 14 h light-10 h dark. The addition of ethanol or malate produced a twofold increase in citrate-synthase activity compared with phototrophic cultures. White and blue light, but not red light, produced a transient repression of the metabolite-induced increase in citrate-synthase activity in division-synchronized cultures. Since only red light could effect a transient increase in the specific activity of mitochondrial enzymes, and the blue-red plastid receptor should respond to both blue and red light, the synthesis of mitochondrial enzymes in regreening cultures may be under the control of a new photoreceptor responding only to red light. In division-synchronized phototrophic cells the primary effector of synthesis of mitochondrial enzymes is not light but carbon nutrition.     

Methylerythritol phosphate pathway to isoprenoids: Kinetic modeling and in silico enzyme inhibitions in Plasmodium falciparum

The methylerythritol phosphate (MEP) pathway of Plasmodium falciparum (P. falciparum) has become an attractive target for anti-malarial drug discovery. This study describes a kinetic model of this pathway, its use in validating 1-deoxy-d-xylulose 5-phosphate reductoisomerase (DXR) as drug target from the systemic perspective, and additional target identification, using metabolic control analysis and in silico inhibition studies. In addition to DXR, 1-deoxy-d-xylulose 5-phosphate synthase (DXS) can be targeted because it is the first enzyme of the pathway and has the highest flux control coefficient followed by that of DXR. In silico inhibition of both enzymes caused large decrement in the pathway flux. An added advantage of targeting DXS is its influence on vitamin B1 and B6 biosynthesis. Two more potential targets, 2-C-methyl-d-erythritol 2,4-cyclodiphosphate synthase and 1-hydroxy-2-methyl-2-(E)-butenyl 4-diphosphate synthase, were also identified. Their inhibition caused large accumulation of their substrates causing instability of the system.     

Characterization of soluble and putative membrane-bound UDP-glucuronic acid decarboxylase (OsUXS) isoforms in rice

Arabinoxylans in crop plants are the major sugar components of the cell walls, and UDP-xylose is a key substrate in the biosynthesis of xylans. In this study, the six putative UDP-D-glucuronic acid decarboxylase genes from rice (Oryza sativa UDP-xylose synthase; OsUXS) were cloned. Except for the soluble form of OsUXS3 (GenBank Accession No. \AB079064), the remaining five OsUXS enzymes contain a putative membrane-bound region. The six OsUXS genes were classified into three types by phylogenetic analysis and were expressed during the development of rice seeds. The HPLC retention times of the enzyme products and NMR data, indicate that the recombinant OsUXS2 enzyme catalyzes the conversion of UDP-D-glucuronic acid to UDP-D-xylose. Interestingly, the reactions catalyzed by the recombinant OsUXS2 and OsUXS3 enzymes were inhibited by NADP+, and accelerated by NADPH. The catalytic activities of the recombinant OsUXS2 and OsUXS3 enzymes were strongly inhibited by UDP, UTP, TDP, and TTP. The expression levels of OsUXS genes changed in different manners during the development of rice seeds, suggesting that each corresponding OsUXS enzyme plays a significant role in rice seed development at a certain stage. In the present study, we report that the UXS2-type enzyme of rice is not only characterized for the first time but also show significant findings involved in the gene expression of OsUXSs.     

A radiotracer enzyme assay for phosphofructokinase using ( , , -32P) adenosine triphosphate

A radiotracer enzyme assay for phosphofructokinase using adenosine 5′-triphosphate[α,β,γ-³²P] is described in this paper. Here the rates of appearance of both [1-³²P]d-fructose 1,6-diphosphate and [α,β-³²P] adenosine 5′-diphosphate were followed to establish enzyme activity. The unique advantages of multiple rate determinations in a single reaction sequence which accrue from the use of a readily available multiply labeled cosubstrate are discussed. By an extension of this approach other labeled(¹) nucleotides of the type, N(¹P)_n, and enzymes in the Enzyme Commision categories, EC 2.7(phosphotransferases) and EC 6.1–6.4(ligases) are equally amenable to radionuclide assay.     

X-ray absorption spectroscopic characterization of the diferric-peroxo intermediate of human deoxyhypusine hydroxylase in the presence of its substrate eIF5a

Human deoxyhypusine hydroxylase (hDOHH) is an enzyme that is involved in the critical post-translational modification of the eukaryotic translation initiation factor 5A (eIF5A). Following the conversion of a lysine residue on eIF5A to deoxyhypusine (Dhp) by deoxyhypusine synthase, hDOHH hydroxylates Dhp to yield the unusual amino acid residue hypusine (Hpu), a modification that is essential for eIF5A to promote peptide synthesis at the ribosome, among other functions. Purification of hDOHH overexpressed in E. coli affords enzyme that is blue in color, a feature that has been associated with the presence of a peroxo-bridged diiron(III) active site. To gain further insight into the nature of the diiron site and how it may change as hDOHH goes through the catalytic cycle, we have conducted X-ray absorption spectroscopic studies of hDOHH on five samples that represent different species along its reaction pathway. Structural analysis of each species has been carried out, starting with the reduced diferrous state, proceeding through its O₂ adduct, and ending with a diferric decay product. Our results show that the Fe?Fe distances found for the five samples fall within a narrow range of 3.4–3.5 Å, suggesting that hDOHH has a fairly constrained active site. This pattern differs significantly from what has been associated with canonical dioxygen activating nonheme diiron enzymes, such as soluble methane monooxygenase and Class 1A ribonucleotide reductases, for which the Fe?Fe distance can change by as much as 1 Å during the redox cycle. These results suggest that the O₂ activation mechanism for hDOHH deviates somewhat from that associated with the canonical nonheme diiron enzymes, opening the door to new mechanistic possibilities for this intriguing family of enzymes.     

Structural characterizations of nonpeptidic thiadiazole inhibitors of matrix metalloproteinases reveal the basis for stromelysin selectivity.

The binding of two 5-substituted-1,3,4-thiadiazole-2-thione inhibitors to the matrix metalloproteinase stromelysin (MMP-3) have been characterized by protein crystallography. Both inhibitors coordinate to the catalytic zinc cation via an exocyclic sulfur and lay in an unusual position across the unprimed (P1-P3) side of the proteinase active site. Nitrogen atoms in the thiadiazole moiety make specific hydrogen bond interactions with enzyme structural elements that are conserved across all enzymes in the matrix metalloproteinase class. Strong hydrophobic interactions between the inhibitors and the side chain of tyrosine-155 appear to be responsible for the very high selectivity of these inhibitors for stromelysin. In these enzyme/inhibitor complexes, the S1'' enzyme subsite is unoccupied. A conformational rearrangement of the catalytic domain occurs that reveals an inherent flexibility of the substrate binding region leading to speculation about a possible mechanism for modulation of stromelysin activity and selectivity.     

Mechanistic similarity and diversity among the guanidine-modifying members of the pentein superfamily

The pentein superfamily is a mechanistically diverse superfamily encompassing both noncatalytic proteins and enzymes that catalyze hydrolase, dihydrolase and amidinotransfer reactions on guanidine substrates. Despite generally low sequence identity, they possess a conserved structural fold and display common mechanistic themes in catalysis. The structurally characterized catalytic penteins possess a conserved core of residues that include a Cys, His and two polar, guanidine-binding residues. All known catalytic penteins use the core Cys to attack the substrate's guanidine moiety to form a covalent thiouronium adduct and all cleave one or more of the guanidine C―N bonds. The mechanistic information compiled to date supports the hypothesis that this superfamily may have evolved divergently from a catalytically promiscuous ancestor.     

Bio-layer Interferometry for Measuring Kinetics of Protein-protein Interactions and Allosteric Ligand Effects

We describe the use of Bio-layer Interferometry to study inhibitory interactions of subunit ε with the catalytic complex of Escherichia coli ATP synthase. Bacterial F-type ATP synthaseis the target of a new, FDA-approved antibiotic to combat drug-resistant tuberculosis. Understanding bacteria-specific auto-inhibition of ATP synthase by the C-terminal domain of subunit ε could provide a new means to target the enzyme for discovery of antibacterial drugs. The C-terminal domain of ε undergoes a dramatic conformational change when the enzyme transitions between the active and inactive states, and catalytic-site ligands can influence which of ε''s conformations is predominant. The assay measures kinetics of ε''s binding/dissociation with the catalytic complex, and indirectly measures the shift of enzyme-bound ε to and from the apparently nondissociable inhibitory conformation. The Bio-layer Interferometry signal is not overly sensitive to solution composition, so it can also be used to monitor allosteric effects of catalytic-site ligands on ε''s conformational changes.     

Structure and Mechanism of Human UDP-xylose Synthase: EVIDENCE FOR A PROMOTING ROLE OF SUGAR RING DISTORTION IN A THREE-STEP CATALYTIC CONVERSION OF UDP-GLUCURONIC ACID

UDP-xylose synthase (UXS) catalyzes decarboxylation of UDP-d-glucuronic acid to UDP-xylose. In mammals, UDP-xylose serves to initiate glycosaminoglycan synthesis on the protein core of extracellular matrix proteoglycans. Lack of UXS activity leads to a defective extracellular matrix, resulting in strong interference with cell signaling pathways. We present comprehensive structural and mechanistic characterization of the human form of UXS. The 1.26-Å crystal structure of the enzyme bound with NAD⁺ and UDP reveals a homodimeric short-chain dehydrogenase/reductase (SDR), belonging to the NDP-sugar epimerases/dehydratases subclass. We show that enzymatic reaction proceeds in three chemical steps via UDP-4-keto-d-glucuronic acid and UDP-4-keto-pentose intermediates. Molecular dynamics simulations reveal that the d-glucuronyl ring accommodated by UXS features a marked ⁴C₁ chair to B_O,3 boat distortion that facilitates catalysis in two different ways. It promotes oxidation at C₄ (step 1) by aligning the enzymatic base Tyr¹⁴⁷ with the reactive substrate hydroxyl and it brings the carboxylate group at C₅ into an almost fully axial position, ideal for decarboxylation of UDP-4-keto-d-glucuronic acid in the second chemical step. The protonated side chain of Tyr¹⁴⁷ stabilizes the enolate of decarboxylated C₄ keto species (²H₁ half-chair) that is then protonated from the Si face at C₅, involving water coordinated by Glu¹²⁰. Arg²⁷⁷, which is positioned by a salt-link interaction with Glu¹²⁰, closes up the catalytic site and prevents release of the UDP-4-keto-pentose and NADH intermediates. Hydrogenation of the C₄ keto group by NADH, assisted by Tyr¹⁴⁷ as catalytic proton donor, yields UDP-xylose adopting the relaxed ⁴C₁ chair conformation (step 3).     

Function, structure and regulation of cyanobacterial and chloroplast ATP synthase

The proton-translocating ATP synthase from chloroplasts and cyanobacteria forms ATP upon photosynthetic electron transport by using the proton gradient across the thylakoid membrane. Both enzymes contain nine different subunits and from the similarity in gene organisation and the high degree of amino acid sequence homology of the subunits it appears that these ATP synthases might have a common ancestor. Both enzymes need to be activated by membrane energisation in order to perform catalytic activity but, in contrast to the chloroplast ATP synthase, that from the studied cyanobacteria (with the exception of Spirulina platensis ) shows no effect of the redox state on activation. Functionally, the cyanobacterial enzyme corresponds to the reduced form of the chloroplast ATP synthase. In the chloroplast enzyme a stretch of 9 amino acids, including two cysteines in the γ-subunit, is involved in this redox effect and this stretch is absent in cyanobacteria. With γ-mutants from the cyanobacterium Synechocystis 6803 the role of this stretch is studied. When active, both the cyanobacterial and the reduced chloroplast ATP synthase transport 4 protons per ATP synthesised and hydrolysed. This ratio may depend on the environment of the enzyme such as protein and lipid composition and pH.     

Regulatory mechanisms of β-glucan synthases in bacteria, fungi, and plants

The evidence accumulated to date indicates that 1,3-β-glucan synthase (EC 2.3.1.12) and 1,4-β-glucan synthase (EC 2.4.1.12) are regulated by different effectors. Further that the same synthase has different effectors, depending upon its presence in green plants, fungi, and bacteria. Synthases from plants require divalent cations and β-linked glucosides whereas fungal enzymes require neither cations nor β-glucosides, but most require nucleoside triphosphates for activation. Two endogenous effectors have been characterized and shown to produce activation in vitro. One is 3',5'-cyclic diguanylic acid that is the activator of cellulose synthase in bacteria. The other is a β-linked glucosyl dioleoyl diglyceride from mung bean, capable of activating synthases that produce both β-(1–3) and β-(1–4) products. The results of product analysis of the β-linked glucoside activated reaction suggest that the synthesis of (1–3) and (1–4) glucosyl linkages may share a common enzyme in plants. All synthases utilize uridine 5'-diphosphoglucose (UDPG) and are associated with the plasma membrane. Efforts to solubilize the synthases from cellular fractions enriched in plasma membranes have been generally successful. The purification of the soluble enzymes, however, remains a major obstacle to the full understanding of their regulation.     

UGD1, encoding the Cryptococcus neoformans UDP-glucose dehydrogenase, is essential for growth at 37 degrees C and for capsule biosynthesis

We report the identification and disruption of the Cryptococcus neoformans var. grubii UGD1 gene encoding the UDP-glucose dehydrogenase, which catalyzes the conversion of UDP-glucose into UDP-glucuronic acid. Deletion of UGD1 led to modifications in the cell wall, as revealed by changes in the sensitivity of ugd1Delta cells to sodium dodecyl sulfate, NaCl, and sorbitol. Moreover, two of the yeast's major virulence factors-capsule biosynthesis and the ability to grow at 37 degrees C-were impaired in ugd1Delta strains. These results suggest that the UDP-dehydrogenase represents the major, and maybe only, biosynthetic pathway for UDP-glucuronic acid in C. neoformans. Consequently, deletion of UGD1 blocked not only the synthesis of UDP-glucuronic acid but also that of UDP-xylose. To differentiate the phenotype(s) associated with the UDP-glucuronic acid defect alone from those linked to the UDP-xylose defect, ugd1Delta mutants were phenotypically compared to strains from which the gene encoding UDP-xylose synthase (i.e., that required for synthesis of UDP-xylose) had been deleted. Finally, studies of strains from which one of the four CAP genes (CAP10, CAP59, CAP60, or CAP64) had been deleted revealed common cell wall phenotypes associated with the acapsular state.     

Enzymes of the mevalonate pathway of isoprenoid biosynthesis

The mevalonate pathway accounts for conversion of acetyl-CoA to isopentenyl 5-diphosphate, the versatile precursor of polyisoprenoid metabolites and natural products. The pathway functions in most eukaryotes, archaea, and some eubacteria. Only recently has much of the functional and structural basis for this metabolism been reported. The biosynthetic acetoacetyl-CoA thiolase and HMG-CoA synthase reactions rely on key amino acids that are different but are situated in active sites that are similar throughout the family of initial condensation enzymes. Both bacterial and animal HMG-CoA reductases have been extensively studied and the contrasts between these proteins and their interactions with statin inhibitors defined. The conversion of mevalonic acid to isopentenyl 5-diphosphate involves three ATP-dependent phosphorylation reactions. While bacterial enzymes responsible for these three reactions share a common protein fold, animal enzymes differ in this respect as the recently reported structure of human phosphomevalonate kinase demonstrates. There are significant contrasts between observations on metabolite inhibition of mevalonate phosphorylation in bacteria and animals. The structural basis for these contrasts has also recently been reported. Alternatives to the phosphomevalonate kinase and mevalonate diphosphate decarboxylase reactions may exist in archaea. Thus, new details regarding isopentenyl diphosphate synthesis from acetyl-CoA continue to emerge.     

Real-time NMR monitoring of intermediates and labile products of the bifunctional enzyme UDP-apiose/UDP-xylose synthase

The conversion of UDP-α-d-glucuronic acid to UDP-α-d-xylose and UDP-α-d-apiose by a bifunctional potato enzyme UDP-apiose/UDP-xylose synthase was studied using real-time nuclear magnetic resonance (NMR) spectroscopy. UDP-α-d-glucuronic acid is converted via the intermediate uridine 5′-β-l-threo-pentapyranosyl-4″-ulose diphosphate to UDP-α-d-apiose and simultaneously to UDP-α-d-xylose. The UDP-α-d-apiose that is formed is unstable and is converted to α-d-apio-furanosyl-1,2-cyclic phosphate and UMP. High-resolution real-time NMR spectroscopy is a powerful tool for the direct and quantitative characterization of previously undetected transient and labile components formed during a complex enzyme-catalyzed reaction.     

Ionizable side chains at catalytic active sites of enzymes

Catalytic active sites of enzymes of known structure can be well defined by a modern program of computational geometry. The CASTp program was used to define and measure the volume of the catalytic active sites of 573 enzymes in the Catalytic Site Atlas database. The active sites are identified as catalytic because the amino acids they contain are known to participate in the chemical reaction catalyzed by the enzyme. Acid and base side chains are reliable markers of catalytic active sites. The catalytic active sites have 4 acid and 5 base side chains, in an average volume of 1,072 Å³. The number density of acid side chains is 8.3 M (in chemical units); the number density of basic side chains is 10.6 M. The catalytic active site of these enzymes is an unusual electrostatic and steric environment in which side chains and reactants are crowded together in a mixture more like an ionic liquid than an ideal infinitely dilute solution. The electrostatics and crowding of reactants and side chains seems likely to be important for catalytic function. In three types of analogous ion channels, simulation of crowded charges accounts for the main properties of selectivity measured in a wide range of solutions and concentrations. It seems wise to use mathematics designed to study interacting complex fluids when making models of the catalytic active sites of enzymes.     

Bioinformatics approaches for structural and functional analysis of proteins in secondary metabolism in Withania somnifera

Withania somnifera (Ashwagandha) is an affluent storehouse of large number of pharmacologically active secondary metabolites known as withanolides. These secondary metabolites are produced by withanolide biosynthetic pathway. Very less information is available on structural and functional aspects of enzymes involved in withanolides biosynthetic pathways of Withiana somnifera. We therefore performed a bioinformatics analysis to look at functional and structural properties of these important enzymes. The pathway enzymes taken for this study were 3-Hydroxy-3-methylglutaryl coenzyme A reductase, 1-Deoxy-d-xylulose-5-phosphate synthase, 1-Deoxy-d-xylulose-5-phosphate reductase, farnesyl pyrophosphate synthase, squalene synthase, squalene epoxidase, and cycloartenol synthase. The prediction of secondary structure was performed for basic structural information. Three-dimensional structures for these enzymes were predicted. The physico-chemical properties such as pI, AI, GRAVY and instability index were also studied. The current information will provide a platform to know the structural attributes responsible for the function of these protein until experimental structures become available.