Two complementary radiometric methods for the measurement of 5-amino-4-imidazole-N-succinocarboxamide ribonucleotide synthetase (SAICAR synthetase)

Two complementary methods have been devised for measuring the activity of 5-amino-4-imidazole-N-succinocarboxamide ribonucleotide synthetase (SAICAR synthetase, EC 6.3.2.6), a critical enzyme in the pathway of purine biosynthesis. In the first method, l-[4.¹⁴C]aspartic acid is condensed with 5-amino-4-imidazolecarboxylic acid ribonucleotide (AICOR) via the action of SAICAR synthetase. Unreacted l-[4-¹⁴C]aspartic acid is measured by scintillation spectrometry. In the second method, the reverse reaction of SAICAR synthetase is measured; radiactive 5-amino-4-imidazole-N-succinocarboxamide ribonucleotide (SAICAR) is synthetized enzymatically, using a partial purified preparation of SAICAR synthetase from chicken liver. To the purified [¹⁴C]SAICAR is added: sodium arsenate, Tris-HCl buffer containing ADPMgCl₂ or buffer alone, and to initiate the reaction, a 12 000 × g supernatant or other suitable source of enzyme. As a consequence of the arsenolytic cleavage of [¹⁴C]SAICAR, l-[4-¹⁴C]aspartic acid is generated in stoichiometric amounts. The fourth carbon of this amino acid is then detached by selective enzymatic decarboxylation, trapped in 40% KOH and quantitated by scintillation spectrometry. The assays, performed as prescribed, are facile and notably sensitive; using them, the specific activity of SAICAR synthetase has been measured in acetone powders of the livers of representative members of the Vertebrata, and also in the principal viscera of the mouse. Of the livers examined, pigeon liver was the richest source of the investigated enzyme.     

A Conserved Histidine Is Essential for Glycerolipid Acyltransferase Catalysis

Sequence analysis of membrane-bound glycerolipid acyltransferases revealed that proteins from the bacterial, plant, and animal kingdoms share a highly conserved domain containing invariant histidine and aspartic acid residues separated by four less conserved residues in an HX₄D configuration. We investigated the role of the invariant histidine residue in acyltransferase catalysis by site-directed mutagenesis of two representative members of this family, the sn-glycerol-3-phosphate acyltransferase (PlsB) and the bifunctional 2-acyl-glycerophosphoethanolamine acyltransferase/acyl-acyl carrier protein synthetase (Aas) of Escherichia coli. Both the PlsB[H306A] and Aas[H36A] mutants lacked acyltransferase activity. However, the Aas[H36A] mutant retained significant acyl-acyl carrier protein synthetase activity, illustrating that the lack of acyltransferase activity was specifically associated with the H36A substitution. The invariant aspartic acid residue in the HX₄D pattern was also important. The substitution of aspartic acid 311 with glutamic acid in PlsB resulted in an enzyme with significantly reduced catalytic activity. Substitution of an alanine at this position eliminated acyltransferase activity; however, the PlsB[D311A] mutant protein did not assemble into the membrane, indicating that aspartic acid 311 is also important for the proper folding and membrane insertion of the acyltransferases. These data are consistent with a mechanism for glycerolipid acyltransferase catalysis where the invariant histidine functions as a general base to deprotonate the hydroxyl moiety of the acyl acceptor.     

不同年龄小白鼠全脑细胞质氨酰tRNA合成酶活力的比较

从不同年龄(20天,30天,1年)的小白鼠全脑制得细胞质混合氨酰tRNA合成酶。用异源体系(即用酵母tRNA和小白鼠全脑氨酰tRNA合成酶)测定了氨酰tRNA合成酶分别载运~3H标记的Asp、Gly、Glu、Lys和Ala的活力。结果表明除未检出tRNA~(Glu)的合成酶活力外,对其余四种氨基酸都有明显的活力,特别是年龄20天小白鼠的氨酰tRNA合成酶对~3H-Gly具有高达35％的载运活力。对~3H-Gly、~3H-Lys和~3H-Ala的载运活力有随增龄而下降的趋势,但对~3H-Asp的载运活力则随年龄增长而增高。     

Studies on the Bacterial Formation of a Peptide Antibiotic,Colistin

The biosynthetic pathway of α,γ-diaminobutyric acid, 6 moles of which are involved in the colistin molecule as a main component, was investigated. On the basis of the isotopic results using aspartic acid-U-¹⁴C as a precursor and also the finding of transaminase activity between α-ketog?utaric acid and α,γ-diaminobutyric acid, though in reverse reaction, α,γ-diaminobutyric acid was proved to be synthesized from aspartic acid via aspartyl-phosphate and aspartic β-semialdehyde. α,γ-Diaminobutyric acid did not inhibit asparto-kinase activity of this bacterium, the first enzyme involved in the process of α,γ-diamino-butyric acid synthesis from aspartic acid, while the end product amino acids such as lysine, threonine and methionine showed inhibition for aspartokinase activity.

On the other hand, α,γ-diaminobutyric acid might be rate-limiting factor in colistin formation, because of stimulatory effect of this diamino acid when added to the medium on colistin production. Furthermore, colistin production appeared to be related with the defect of TCA-cycle and further the resultant increase in activities of the key enzymes such as isopropylmalate synthetase, α-acetolactate synthetase and aspartokinase involved in the biosynthetic pathways of valine, leucine and isoleucine, respectively.     

Biosynthesis of the cyanobacterial reserve polymer multi-L-arginyl-poly-L-aspartic acid (cyanophycin): mechanism of the cyanophycin synthetase reaction studied with synthetic primers.

Biosynthesis of the cyanobacterial nitrogen reserve cyanophycin (multi-L-arginyl-poly-L-aspartic acid) is catalysed by cyanophycin synthetase, an enzyme that consists of a single kind of polypeptide. Efficient synthesis of the polymer requires ATP, the constituent amino acids aspartic acid and arginine, and a primer like cyanophycin. Using synthetic peptide primers, the course of the biosynthetic reaction was studied. The following results were obtained: (a) sequence analysis suggests that cyanophycin synthetase has two ATP-binding sites and hence probably two active sites; (b) the enzyme catalyses the formation of cyanophycin-like polymers of 25-30 kDa apparent molecular mass in vitro; (c) primers are elongated at their C-terminus; (d) the constituent amino acids are incorporated stepwise, in the order aspartic acid followed by arginine, into the growing polymer. A mechanism for the cyanophycin synthetase reaction is proposed; (e) the specificity of the enzyme for its amino-acid substrates was also studied. Glutamic acid cannot replace aspartic acid as the acidic amino acid, whereas lysine can replace arginine but is incorporated into cyanophycin at a much lower rate.     

The fidelity of protein synthesis: can mischarging by aspartyl-tRNA(Asp) synthetase lead to the formation of isoaspartyl residues in proteins?

We have tested the hypothesis that isoaspartic acid residues in proteins can arise via errors that occur during protein synthesis. One such error involves a mischarging step in which the aspartic acid side-chain beta-carboxyl group is linked to the tRNA(Asp) instead of the main chain alpha-carboxyl group. If this altered Asp-tRNA(Asp) is a substrate for the ribosomal elongation reactions, a polypeptide will be made with an isoaspartic acid, or beta-linkage, in which the peptide chain is branched at the side chain of the aspartic acid residue. Using an ammonium sulfate fraction of aspartyl-tRNA(Asp) synthetase from Escherichia coli and [3H]aspartic acid, we have prepared [3H]aspartyl-tRNA(Asp) complexes and directly analyzed the linkage of the [3H]aspartate to the tRNA by identifying the products of ammonolysis. Normal attachment of the alpha-carboxyl group of aspartate to the tRNA produces [3H]isoasparagine, while the mischarging reaction leads to [3H]asparagine formation after ammonolysis. We have separated [3H]isoasparagine from [3H]asparagine and found an upper limit of 1 asparagine per 10,000 isoasparagines. These results show that the bacterial aminoacyl-tRNA synthetase can very accurately distinguish between the alpha- and beta-carboxyl groups of aspartic acid and suggest that only a very small fraction of the isoaspartic acid residues found to occur in cellular proteins may be the result of mischarging steps.     

A C-NMR study on the influxes into the tricarboxylic acid cycle of a renal epithelial cell line, LLC-PK1/Cl4: the metabolism of [2-C]glycine, l-[3-C]alanine and l-[3-C]aspartic acid in renal epithelial cells

Perchloric acid extracts of LLC-PK₁/Cl₄ cells, a renal epithelial cell line, incubated with either [2-¹³C]glycine l-[3-¹³C]alanine, or d,l-[3-¹³C]aspartic acid were investigated by ¹³C-NMR spectroscopy. All amino acids, except labelled glycine, gave rise to glycolytic products and tricarboxylic acid cycle (TCA) intermediates. For the first time we also observed activity of γ-glutamyltransferase activity and glutathione synthetase activity in LLC-PK₁ cells, as is evident from enrichment of reduced glutathione. Time courseS showed that only 6% of the labelled glycine was utilized in 30 min, whereas 31% of l-alanine and 60% of l-aspartic acid was utilized during the same period. ¹³C-NMR was also shown to be a useful tool for the determination of amino acid uptake in LLC-PK₁ cells. These uptake experiments indicated that glycine alanine and aspartic acid are transported into Cl₄ cells via a sodium-dependent process. From the relative enrichment of the glutamate carbons, we calculated the activity of pyruvate dehydrogenase to be about 61% of when labelled l-alanine was the only carbon source for LLC-PK₁/Cl₄ cells. Experiments with labelled d,l-aspartic, however, showed that about 40% of C-3-enriched oxaloacetate (arising from a de-amination of aspartic acid) reached the pyruvate pool.     

Isolation and properties of phosphoribosyl-aminoimidazole-succinocarboxyamide-synthestase from Saccharomyces cerevisiae yeasts

An isolation procedure for phosphoribosyl succinocarboxamideaminoimidazole synthetase (SAICAR synthetase) (EC 6.3.2.6) has been developed. Pure SAICAR synthetase was found to be a monomeric protein with the apparent molecular weight of 36 kDa. The Michaelis constant for the three substrates of the reaction are 1.6 microM for CAIR, 14 microM for ATP and 960 microM for aspartic acid. The structural analogs of CAIR, 5-aminoimidazole ribotide and 5-aminoimidazole-4-carboxamide ribotide, act as competitive inhibitors of SAICAR synthetase. GTP and 2'-dATP can substitute for ATP in the reaction, while CTP and UTP inhibit the enzyme. No structural analogs of the aspartic acid were found to have affinity for SAICAR synthetase. The optimal reaction conditions for the enzyme were established to be at pH 8.0 and magnesium chloride concentration around 5 mM.     

Expression of Synechocystis sp. PCC6803 cyanophycin synthetase in Lactococcus lactis nisin-controlled gene expression system (NICE) and cyanophycin production

Cyanophycin is a natural source of polypetide consisting of aspartic acid as a backbone and arginine as its side chain. After the removal of arginine, the remaining poly-aspartate can be served in numerous industrial and biomedical applications. The synthesis of cyanophycin is catalyzed by cyanophycin synthetase. In this study, we used lactic acid bacteria to produce cyanophycin by nisin-controlled gene expression system (NICE). The cyanophycin synthetase gene cphA of Synechocystis sp. strain PCC6803 was cloned to the vector pNZ8149 followed by transformation into Lactococcus lactis subsp. cremoris NZ3900. The effects of nisin concentrations and the amounts of supplemented aspartic acid and arginine were examined for the production of cyanophycin. Alterations of the terminus of cphA gene were also conducted in an attempt to increase the yield of cyanophycin. An optimal cyanophycin production was noted under a culture condition of log phase induced at 250 ng/mL nisin in M17L medium supplemented with 20 mM arginine and 10 mM aspartic acid. An insertion of glycine residue at the C terminus of cyanophycin synthetase resulted in a yield of 20% of dry cell weight, a 10-fold increase when compared with the wild type. The results showed that recombinant lactic acid bacteria, a GRAS system, could provide an alternative approach of producing cyanophycin suitable for agricultural and biomedical applications.     

The crystal structure of asparaginyl-tRNA synthetase from Thermus thermophilus and its complexes with ATP and asparaginyl-adenylate: the mechanism of discrimination between asparagine and aspartic acid.

The crystal structure of Thermus thermophilus asparaginyl-tRNA synthetase has been solved by multiple isomorphous replacement and refined at 2.6 A resolution. This is the last of the three class IIb aminoacyl-tRNA synthetase structures to be determined. As expected from primary sequence comparisons, there are remarkable similarities between the tertiary structures of asparaginyl-tRNA synthetase and aspartyl-tRNA synthetase, and most of the active site residues are identical except for three key differences. The structure at 2.65 A of asparaginyl-tRNA synthetase complexed with a non-hydrolysable analogue of asparaginyl-adenylate permits a detailed explanation of how these three differences allow each enzyme to discriminate between their respective and very similar amino acid substrates, asparagine and aspartic acid. In addition, a structure of the complex of asparaginyl-tRNA synthetase with ATP shows exactly the same configuration of three divalent cations as previously observed in the seryl-tRNA synthetase-ATP complex, showing that this a general feature of class II synthetases. The structural similarity of asparaginyl- and aspartyl-tRNA synthetases as well as that of both enzymes to the ammonia-dependent asparagine synthetase suggests that these three enzymes have evolved relatively recently from a common ancestor.     

Biopterin

Three specific enzymes are involved in the cerebral synthesis of 7,8-dihydrobiopterin from GTP. These were isolated, purified, and characterized. The first enzyme, also catalyzing the rate-limiting step, is GTP-cyclohydrolase A-I or Mg²⁺-dependent A-II, which hydrolyze the GTP to the specific product 2-amino-6-(5-triphosphoribosyl)-amino-5-or-6-formamido-6-hydroxypyrimidine (FPyd-P₃). FPyd-P₃ is cyclized by a synthetase tod-erythro-7,8-dihydroneopterintriphosphate (NPTH₂-P₃). The new enzyme,d-erythro-7,8-dihydroneopterintriphosphate synthetase (enzyme B) is a basic protein of 9177 daltons containing three free SH groups, isoleucyl-seryl- as N- and valyl-glutamyl- as C-terminals. This enzyme of 69 amino acid residues from rat and 68 residues (one less aspartic acid) from guinea pig brain contains no hydroxyproline, methionine, or tryptophan. The enzyme from rat brain will gradually convert its product NPTH₂-P₃ to BH₂, whereas the enzyme from guinea pig brain lacks this property. 2,4-amino-6-hydroxypyrimidine and dFPyd-P₃ are effective inhibitors of this enzyme. The synthesis of BH₂ from NPTH₂-P₃, but not from 7,8-dihydroneopterin, is catalyzed byl-erythro-7,8-dihydrobiopterin synthetase (enzyme C), which was purified to electrophoretic purity. This enzyme does not require pyridine nucleotides or Mg²⁺ for its catalysis.     

Nitrogenase activity,amino acid pool patterns and amination in blue-green algae

Summary The free amino acid pools in the nitrogen-fixing blue-green algae Anabaena cylindrica, A. flos-aquae and Westiellopsis prolifica contain a variety of amino acids with aspartic acid, glutamic acid and the amide glutamine being present in much higher concentrations than the others. This pattern is characteristic of that found in organisms having glutamine synthetage/glutamate synthetase [glutamine amide-2-oxoglutarate amino transferase (oxido-reductase)] as an important pathway of ammonia incorporation. Under nitrogen-starved conditions the level of acetylene reduction (nitrogen fixation) and the glutamine pool both increase but the free ammonia pool decreases, suggesting that ammonia rather than glutamine regulates nitrogen fixation.Glutamine synthetase has been demonstrated in Anabaena cylindrica using the -glutamyl transferase assay and also using a biosynthetic assay in which P_i release from ATP during glutamine synthesis was measured. The enzyme (-glutamyl transferase assay) is present in nitrogen-fixing cultures and activity is higher in aerobic than in microaerophilic cultures. Ammonium-grown cultures have lowest levels of all and activity in the presence of nitrate-nitrogen (150 mg nitrogen 1^-1) is lower than in aerobic cultures growing on elemental nitrogen. Ammonium-nitrogen and nitrate-nitrogen have no effect on glutamine synthetase in vitro. Glutamate synthetase also operates in nitrogen-fixing cultures of Anabaena cylindrica.     

STUDIES ON FUNCTIONAL AND METABOLIC ROLE OF UREA CYCLE INTERMEDIATES IN BRAIN

Abstract— The distribution of argininosuccinate synthetase, argininosuccinase and arginase, and the synthesis of urea in cerebullum. cerebral cortex and brain stem have been studied. Cerebral cortex had high levels of argininosuccinate synthetase and argininosuccinase. and a high ability to synthesize urea from aspartic acid and citrulline. Of the three regions, cerebullum had the highest arginase activity. The activities of the enzymes transamidinase and ornithine aminotransferase in the metabolism of arginine and ornithine in pathways other than urea formation have been studied in the three regions of the rat brain. The activity of creatine phosphokinase in all regions was the same: carbamylphosphatase activity was highest in cerebullum. Cerebral cortex had a high activity of aspartic acid transcarba-mylase. The brain stem, among the three regions, had the lowest activities of glutamine synthetase and glutaminase. The activities of these enzymes in the different regions are discussed in relation to urea production and the utilization of the urea cycle intermediates.
Intraperitoneal injection of high amounts of citrulline brought about a rise in the glutamine synthetase activity of cerebellum and brain stem and a rise in ornithine aminotransferase in cerebral cortex and liver. These results are discussed in relation to the mechanism of action of citrulline in alleviating the toxicity in hyperammonaemic states.     

Stimulatory Effect of Aspartic Acid on Colistin Production by Bacillus polymyxa

The effect of amino acids on colistin production was investigated with Bacillus polymyxa var. KY-7584. Aspartic acid, the precursor of α,γ-diaminobutyric acid (one of the structural components of colistin), showed a remarkable difference of colistin production between Morido’s fermentation medium and the modified medium containing the appropriate concentrations of phosphate ion (PO₄^3-) and ammonium-nitrogen (NH₄-N). Further studies revealed that a main factor which controlled the stimulatory effect of aspartic acid on colistin production was PO₄^3- . The optimum concentrations of aspartic acid, PO₄^3- and NH₄-N in the medium for colistin production were above 0.2%, below 0.01% and 0.17%, respectively. The maximum titer of colistin (51,900 u/ml) by the addition of 0.25% aspartic acid showed the increment of about 30% as compared with that in the reference medium. However, the increase of cell concentration was slight. This study also showed that PO₄^3- was an effector to inhibit the metabolic pathwy from aspartic acid to α,γ-diaminobutyric acid.     

Effect of Dietary Addition of Amino Acids and Proteins on the Activities of Some Urea Cycle Enzymes in Rat Liver

The activities of ornithine transcarbamylase, arginine synthetase and arginase in the liver of rats receiving basal diets containing 25% casein supplemented respectively with arginine, aspartic acid, glutamic acid, glycine, a mixture of arginine, aspartic acid and glutamic acid, egg albumin, casein, wheat gluten and gelatin have been determined.

These urea cycle enzymes in rats receiving diets supplemented with the various nitrogen sources were generally increased, but the increments were due to the increase of the ingested amount of nitrogen, and not the specific effect of the individual amino acids or proteins. The excretion of urinary urea in general was increased proportionally with the elevations of these enzyme activities, independent of the nature of the dietary nitrogen.     

The active site of yeast aspartyl-tRNA synthetase: structural and functional aspects of the aminoacylation reaction.

The crystal structures of the various complexes formed by yeast aspartyl-tRNA synthetase (AspRS) and its substrates provide snapshots of the active site corresponding to different steps of the aminoacylation reaction. Native crystals of the binary complex tRNA-AspRS were soaked in solutions containing the two other substrates, ATP (or its analog AMPPcP) and aspartic acid. When all substrates are present in the crystal, this leads to the formation of the aspartyl-adenylate and/or the aspartyl-tRNA. A class II-specific pathway for the aminoacylation reaction is proposed which explains the known functional differences between the two classes while preserving a common framework. Extended signature sequences characteristic of class II aaRS (motifs 2 and 3) constitute the basic functional unit. The ATP molecule adopts a bent conformation, stabilized by the invariant Arg531 of motif 3 and a magnesium ion coordinated to the pyrophosphate group and to two class-invariant acidic residues. The aspartic acid substrate is positioned by a class II invariant acidic residue, Asp342, interacting with the amino group and by amino acids conserved in the aspartyl synthetase family. The amino acids in contact with the substrates have been probed by site-directed mutagenesis for their functional implication.     

Propagation of Biochirality: Crossovers and Nonclassical Crystallization Kinetics of Aspartic Acid in Water

All experimental procedures discussed could be treated as a screening tool for probing the existence of molecular association among the chiral molecules and the solvent system. The molecular association phases of a racemic conglomerate solution (CS) and a racemic compound solution (RCS), and the templating effect of aspartic acid solid surface were observed to minimize the chance of redissolving racemic conglomerate and racemic compound aspartic acid in water and reforming an RCS in crossovers experiments. Only 1 %wt% of l‐aspartic acid was adequate enough to induce a transformation from a racemic compound aspartic acid to a racemic conglomerate aspartic acid. This would make the propagation of biochirality more feasible and sound. However, tetrapeptide, (l‐aspartic acid)₄, failed to induce enantioseparation as templates purely by crystallization. Nonclassical crystallization theory was needed to take into account the existence of a CS. Fundamental parameters of the crystallization kinetics such as the induction time, interfacial energy, Gibbs energetic barrier, nucleation rate, and critical size of stable nuclei of: (i) racemic compound aspartic acid, (ii) racemic compound aspartic acid seeded with 1 %wt% l‐aspartic acid, (iii) racemic conglomerate aspartic acid, and (iv) l‐aspartic acid were evaluated and compared with different initial supersaturation ratios. Morphological studies of crystals grown from the crystallization kinetics were also carried out.Chirality 25:768–779, 2013. © 2013 Wiley Periodicals, Inc.     

Isoaccepting transfer ribonucleic acids in liver and brain of young and old BC3F1 mice

Transfer RNAs from liver and brain of young and old BC3F₁ mice were compared in regard to extent of aminoacylation and cochromatographic profiles of isoaccepting tRNA species on reversed-phase columns. Homologous synthetase preparations and optimal aminoacylation conditions were employed, having been determined for each amino acid and found to be the same for those from old and young mice. Small differences were found between tRNAs from young and old mice in the extent of acceptance for arginine and tyrosine in the liver and for aspartic acid in the brain. There were no differences observed between preparations from young and old mice in any of the cochromatographic profiles for the amino acids examined in this study, which included arginyl-, aspartyl-, glutamyl-, histidyl-, leucyl-, lysyl-, phenylalanyl-, seryl-, and tyrosyl-tRNAs from liver and arginyl-, aspartyl-, histidyl-, leucyl-, lysyl-, and seryl-tRNAs from brain. Comparisons of tRNA preparations from fetal and neonatal liver with those from adult liver did reveal both qualitative and quantitative differences. These results suggest that the postulated accumulation of errors as a result of age-related alterations in the translational mechanism does not occur in tRNA or aminoacyl-tRNA synthetases of these two tissues.     

Characterization of three-fraction mycobacillin synthetase.

Mycobacillin synthetase lacks aspartic acid racemase, alanine racemase and glutamic acid racemase activities. The enzyme also does not respond to ATP-[32P]Pi exchange, nor does it catalyse the antibiotic synthesis in presence of amino acids of configuration opposite to that present in the molecule. Preincubation with optical isomers of opposite configuration inhibited the ATP-[32P]Pi exchange reaction to the extent of 60-90%. None of the three fractions of mycobacillin synthetase contained a pantothenic acid arm. Two molecules of ATP are required to synthesize one peptide bond of mycobacillin. Intermediate peptides of mycobacillin are not covalently linked to the three-fraction mycobacillin synthetase.