guanosine-triphosphate and diphosphoric-acid

The phosphofructokinase (Pfk) reaction represents one of the key regulatory points in glycolysis. While most organisms encode for Pfks that use ATP as phosphoryl donor, some organisms also encode for PP

Topics: Adenosine Triphosphate; Amino Acid Sequence; Bacteria; Clostridium thermocellum; Diphosphates; Guanosine Triphosphate; Kinetics; Phosphofructokinase-1; Phosphofructokinases

Guanosine triphosphate (GTP) cyclohydrolase II (RibA) is one of three enzymes that hydrolytically cleave the C8-N9 bond of the GTP guanine. RibA also catalyzes a subsequent hydrolytic attack at the base liberating formate and in addition cleaves the α-β phosphodiester bond of the triphosphate to form pyrophosphate (PPi). These hydrolytic reactions are promoted by tandem active-site metal ions, zinc and magnesium, that respectively function at the GTP guanine and triphosphate moieties. The RibA reaction is part of riboflavin biosynthesis and forms 2,5-diamino-6-β-pyrimidinone 5'-phosphate, an exocyclic pyrimidine nucleotide that ultimately forms the pyrimidine ring of the isoalloxazine of riboflavin. The stoichiometry of the RibA reaction was defined in the study that first identified this activity in

Topics: Biocatalysis; Diphosphates; Escherichia coli; Escherichia coli Proteins; GTP Cyclohydrolase; Guanosine Triphosphate; Inosine Triphosphate; Kinetics; Protein Binding; Pyrophosphatases

The catalytic subunit of SARS-CoV-2 RNA-dependent RNA polymerase (RdRp) contains two active sites that catalyze nucleotidyl-monophosphate transfer (NMPylation). Mechanistic studies and drug discovery have focused on RNA synthesis by the highly conserved RdRp. The second active site, which resides in a Nidovirus RdRp-Associated Nucleotidyl transferase (NiRAN) domain, is poorly characterized, but both catalytic reactions are essential for viral replication. One study showed that NiRAN transfers NMP to the first residue of RNA-binding protein nsp9; another reported a structure of nsp9 containing two additional N-terminal residues bound to the NiRAN active site but observed NMP transfer to RNA instead. We show that SARS-CoV-2 RdRp NMPylates the native but not the extended nsp9. Substitutions of the invariant NiRAN residues abolish NMPylation, whereas substitution of a catalytic RdRp Asp residue does not. NMPylation can utilize diverse nucleotide triphosphates, including remdesivir triphosphate, is reversible in the presence of pyrophosphate, and is inhibited by nucleotide analogs and bisphosphonates, suggesting a path for rational design of NiRAN inhibitors. We reconcile these and existing findings using a new model in which nsp9 remodels both active sites to alternately support initiation of RNA synthesis by RdRp or subsequent capping of the product RNA by the NiRAN domain.

Topics: Amino Acid Sequence; Catalytic Domain; Coenzymes; Coronavirus RNA-Dependent RNA Polymerase; Diphosphates; Diphosphonates; Guanosine Triphosphate; Manganese; Models, Molecular; Nidovirales; Nucleotides; Protein Domains; RNA-Binding Proteins; RNA-Dependent RNA Polymerase; SARS-CoV-2; Uridine Triphosphate; Viral Nonstructural Proteins

A chemiluminescent method is proposed for quantitation of NO generation in cell cultures. The method is based on activation of soluble guanylyl cyclase by NO. The product of the guanylyl cyclase reaction, pyrophosphate, is converted to ATP by ATP sulfurylase and ATP is detected in a luciferin-luciferase system. The method has been applied to the measurement of NO generated by activated murine macrophages (RAW 264.7) and bovine aortic endothelial cells. For macrophages activated by lipopolysaccharide and γ-interferon, the rate of NO production is about 100 amol/(cell·min). The rate was confirmed by the measurements of nitrite, the product of NO oxidation. For endothelial cells, the basal rate of NO generation is 5 amol/(cell·min); the rate approximately doubles upon activation by bradykinin, Ca(2+) ionophore A23187 or mechanical stress. For both types of cells the measured rate of NO generation is strongly affected by inhibitors of NO synthase. The sensitivity of the method is about 50 pM/min, allowing the registration of NO generated by 10(2)-10(4) cells. The enzyme-linked chemiluminescent method is two orders of magnitude more sensitive than fluorescent detection using 4-amino-5-methylamino-2',7'-difluorofluorescein (DAF-FM).

Topics: Animals; Aorta; Biological Assay; Bradykinin; Cattle; Cell Line; Cyclic GMP; Diphosphates; Endothelial Cells; Firefly Luciferin; Guanosine Triphosphate; Guanylate Cyclase; Lipopolysaccharides; Luciferases; Luminescence; Luminescent Measurements; Macrophages; Mice; Nitric Oxide; Nitric Oxide Donors; Nitrites; Nitroso Compounds; Receptors, Cytoplasmic and Nuclear; Sensitivity and Specificity; Soluble Guanylyl Cyclase; Sulfate Adenylyltransferase

In eukaryotes, the tRNA(His) guanylyltransferase (Thg1) catalyzes 3'-5' addition of a single guanosine residue to the -1 position (G-1) of tRNA(His), across from a highly conserved adenosine at position 73 (A73). After addition of G-1, Thg1 removes pyrophosphate from the tRNA 5'-end, generating 5'-monophosphorylated G-1-containing tRNA. The presence of the 5'-monophosphorylated G-1 residue is important for recognition of tRNA(His) by its cognate histidyl-tRNA synthetase. In addition to the single-G-1 addition reaction, Thg1 polymerizes multiple G residues to the 5'-end of tRNA(His) variants. For 3'-5' polymerization, Thg1 uses the 3'-end of the tRNA(His) acceptor stem as a template. The mechanism of reverse polymerization is presumed to involve nucleophilic attack of the 3'-OH from each incoming NTP on the intact 5'-triphosphate created by the preceding nucleotide addition. The potential exists for competition between 5'-pyrophosphate removal and 3'-5' polymerase reactions that could define the outcome of Thg1-catalyzed addition, yet the interplay between these competing reactions has not been investigated for any Thg1 enzyme. Here we establish transient kinetic assays to characterize the pyrophosphate removal versus nucleotide addition activities of yeast Thg1 with a set of tRNA(His) substrates in which the identity of the N-1:N73 base pair was varied to mimic various products of the N-1 addition reaction catalyzed by Thg1. We demonstrate that retention of the 5'-triphosphate is correlated with efficient 3'-5' reverse polymerization. A kinetic partitioning mechanism that acts to prevent addition of nucleotides beyond the -1 position with wild-type tRNA(His) is proposed.

Topics: Base Pair Mismatch; Base Pairing; Biocatalysis; Diphosphates; Guanosine Triphosphate; Kinetics; Nucleotides; Nucleotidyltransferases; Reproducibility of Results; RNA, Transfer; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins

Cofactor specificities of glycolytic enzymes in Clostridium thermocellum were studied with cellobiose-grown cells from batch cultures. Intracellular glucose was phosphorylated by glucokinase using GTP rather than ATP. Although phosphofructokinase typically uses ATP as a phosphoryl donor, we found only pyrophosphate (PPi)-linked activity. Phosphoglycerate kinase used both GDP and ADP as phosphoryl acceptors. In agreement with the absence of a pyruvate kinase sequence in the C. thermocellum genome, no activity of this enzyme could be detected. Also, the annotated pyruvate phosphate dikinase (ppdk) is not crucial for the generation of pyruvate from phosphoenolpyruvate (PEP), as deletion of the ppdk gene did not substantially change cellobiose fermentation. Instead pyruvate formation is likely to proceed via a malate shunt with GDP-linked PEP carboxykinase, NADH-linked malate dehydrogenase, and NADP-linked malic enzyme. High activities of these enzymes were detected in extracts of cellobiose-grown cells. Our results thus show that GTP is consumed while both GTP and ATP are produced in glycolysis of C. thermocellum. The requirement for PPi in this pathway can be satisfied only to a small extent by biosynthetic reactions, in contrast to what is generally assumed for a PPi-dependent glycolysis in anaerobic heterotrophs. Metabolic network analysis showed that most of the required PPi must be generated via ATP or GTP hydrolysis exclusive of that which happens during biosynthesis. Experimental proof for the necessity of an alternative mechanism of PPi generation was obtained by studying the glycolysis in washed-cell suspensions in which biosynthesis was absent. Under these conditions, cells still fermented cellobiose to ethanol.

Topics: Adenosine Triphosphate; Bacterial Proteins; Cellobiose; Clostridium thermocellum; Diphosphates; Enzymes; Fermentation; Glucose; Glycogen; Glycolysis; Guanosine Triphosphate; Phosphorylation; Pyruvate, Orthophosphate Dikinase; Sequence Deletion