In vitro assembly of a complete, pentaglycine interpeptide bridge containing cell wall precursor (lipid II-Gly5) of Staphylococcus aureus.

Staphylococcus aureus peptidoglycan is cross-linked via a characteristic pentaglycine interpeptide bridge. Genetic analysis had identified three peptidyltransferases, FemA, FemB and FemX, to catalyse the formation of the interpeptide bridge, using glycyl t-RNA as Gly donor. To analyse the pentaglycine bridge formation in vitro, we purified the potential substrates for FemA, FemB and FemX, UDP-MurNAc-pentapeptide, lipid I and lipid II and the staphylococcal t-RNA pool, as well as His-tagged Gly-tRNA-synthetase and His-tagged FemA, FemB and FemX. We found that FemX used lipid II exclusively as acceptor for the first Gly residue. Addition of Gly 2,3 and of Gly 4,5 was catalysed by FemA and FemB, respectively, and both enzymes were specific for lipid II-Gly1 and lipid II-Gly3 as acceptors. None of the FemABX enzymes required the presence of one or two of the other Fem proteins for activity; rather, bridge formation was delayed in the in vitro system when all three enzymes were present. The in vitro assembly system described here will enable detailed analysis of late, membrane-associated steps of S. aureus peptidoglycan biosynthesis.

Glycyl-tRNA synthetase uses a negatively charged pit for specific recognition and activation of glycine.

The crystal structures of glycyl-tRNA synthetase (GlyRS) from Thermus thermophilus, a homodimeric class II enzyme, were determined in the enzyme-substrate and enzyme-product states corresponding to the first step of aminoacylation. GlyRS was cocrystallized with glycine and ATP, which were transformed by the enzyme into glycyl-adenylate and thus gave the enzyme-product complex. To trap the enzyme-substrate complex, the enzyme was combined with the glycine analog ethanolamine and ATP. The ligands are bound in fixed orientations in the substrate-binding pocket of the N-terminal active site domain, which contains the classical class II aminoacyl-tRNA synthetase (aaRS) fold. Since glycine does not possess a side-chain, much of the specificity of the enzyme is directed toward excluding any additional atoms beyond the alpha-carbon atom. Several carboxylate residues of GlyRS line the glycine binding pocket; two of them interact directly with the alpha-ammonium group. In addition, the enzyme utilizes the acidic character of the pro-L alpha-hydrogen atom by contacting it via a glutamate carboxylic oxygen atom. A guanidino eta-nitrogen atom of the class II aaRS-conserved motif 2 arginine interacts with the substrate carbonyl oxygen atom. These features serve to attract the small amino acid substrate into the active site and to position it in the correct orientation. GlyRS uses class II-conserved residues to interact with the ATP and the adenosine-phosphate moiety of glycyl-adenylate. On the basis of this similarity, we propose that GlyRS utilizes the same general mechanism as that employed by other class II aminoacyl-tRNA synthetases.

An example of non-conservation of oligomeric structure in prokaryotic aminoacyl-tRNA synthetases. Biochemical and structural properties of glycyl-tRNA synthetase from Thermus thermophilus.

Glycyl-tRNA synthetase (Gly-tRNA synthetase) from Thermus thermophilus was purified to homogeneity and with high yield using a five-step purification procedure in amounts sufficient to solve its crystallographic structure [Logan, D.T., Mazauric, M.-H., Kern, D. & Moras, D. (1995) EMBO J. 14, 4156-4167]. Molecular-mass determinations of the native and denatured protein indicate an oligomeric structure of the alpha 2 type consistent with that found for eukaryotic Gly-tRNA synthetases (yeast and Bombyx mori), but different from that of Gly-tRNA synthetases from mesophilic prokaryotes (Escherichia coli and Bacillus brevis) which are alpha 2 beta 2 tetramers. N-terminal sequencing of the polypeptide chain reveals significant identity, reaching 50% with those of the eukaryotic enzymes (B. mori, Homo sapiens, yeast and Caenorhabditis elegans) but no significant identity was found with both alpha and beta chains of the prokaryotic enzymes (E. coli, Haemophilus influenzae and Coxiella burnetii) albeit the enzyme is deprived of the N-terminal extension characterizing eukaryotic synthetases. Thus, the thermophilic Gly-tRNA synthetase combines strong structural homologies of eukaryotic Gly-tRNA synthetases with a feature of prokaryotic synthetases. Heat-stability measurements show that this synthetase keeps its ATP-PPi exchange and aminoacylation activities up to 70 degrees C. Glycyladenylate strongly protects the enzyme against thermal inactivation at higher temperatures. Unexpectedly, tRNA(Gly) does not induce protection. Cross-aminoacylations reveal that the thermophilic Gly-tRNA synthetase charges heterologous E. coli tRNA(gly(GCC)) and tRNA(Gly(GCC)) and yeast tRNA(Gly(GCC)) as efficiently as T. thermophilus tRNA(Gly). All these aminoacylation reactions are characterized by similar activation energies as deduced from Arrhenius plots. Therefore, contrary to the E. coli and H. sapiens Gly-tRNA synthetases, the prokaryotic thermophilic enzyme does not possess a strict species specificity. The results are discussed in the context of the three-dimensional structure of the synthetase and in the view of the particular evolution of the glycinylation systems.

Glycyl-tRNA synthetase.

Glycyl-tRNA synthetase, a class II aminoacyl-tRNA synthetase, catalyzes the synthesis of glycyl-tRNA, which is required to insert glycine into proteins. In a side reaction the enzyme also synthesizes dinuceloside polyphosphates, which probably participate in regulation of cell functions. Glycine is the smallest amino acid occurring in natural proteins, probably established as a protein component very early in evolution. Besides the amino and the carboxyl groups there is no functional group in the molecule. Alanine, the amino acid which is structurally most similar to glycine, possesses an additional methyl group as 'side chain'. Glycyl-tRNA synthetase is one of the few synthetases which exhibit different oligomeric structures in different organisms (alpha 2 beta 2 and alpha 2). The alpha 2 beta 2 enzymes exhibit similarities to PheRS (also an alpha 2 beta 2 enzyme). The alpha 2 forms belong to the subclass IIa enzymes with regard to sequence homologies. In eukaryotes the polypeptide is weakly associated with multienzyme complexes consisting of aminoacyl-tRNA synthetases. In the aminoacylation reaction a 'half-of-the-sites' mechanism as found for GlyRS from Bombyx mori is probably used by all glycyl-tRNA synthetases under in vivo conditions. Essentially, tRNAGly is recognized by GlyRS through standard identity elements in the anticodon region and in the acceptor stem. The last three facts may indicate that GlyRS is an enzyme which still possesses properties of a primordial aminoacyl-tRNA synthetase. Nine genes of glycyl-tRNA synthetases from six organisms have been sequenced. They encode synthetase subunits of chain lengths ranging from 300-700 amino acids. One crystal structure, that of the alpha 2 enzyme from Thermus thermophilus, has also been determined. The two subunits each possess three domains: the active site resembling that of aspartyl and seryl enzymes, a C-terminal anticodon recognition domain, and one domain which almost certainly interacts with the acceptor stem of tRNAGly. Antibodies against glycyl-RNA synthetase occur in the sera of patients suffering from polymyositis and interstitial lung disease.

Crystal structure of glycyl-tRNA synthetase from Thermus thermophilus.

The sequence and crystal structure at 2.75 A resolution of the homodimeric glycyl-tRNA synthetase from Thermus thermophilus, the first representative of the last unknown class II synthetase subgroup, have been determined. The three class II synthetase sequence motifs are present but the structure was essential for identification of motif 1, which does not possess the proline previously believed to be an essential class II invariant. Nevertheless, crucial contacts with the active site of the other monomer involving motif 1 are conserved and a more comprehensive description of class II now becomes possible. Each monomer consists of an active site strongly resembling that of the aspartyl and seryl enzymes, a C-terminal anticodon recognition domain of 100 residues and a third domain unusually inserted between motifs 1 and 2 almost certainly interacting with the acceptor arm of tRNA(Gly). The C-terminal domain has a novel five-stranded parallel-antiparallel beta-sheet structure with three surrounding helices. The active site residues most probably responsible for substrate recognition, in particular in the Gly binding pocket, can be identified by inference from aspartyl-tRNA synthetase due to the conserved nature of the class II active site.

Subunit structure and tRNA-binding properties of Bombyx mori Glycyl-tRNA synthetase.

Large amounts of glycyl-tRNA synthetase were purified from the posterior silk glands of Bombyx mori. The synthetase was estimated to be a dimer with a molecular weight of 180,000. When the enzyme solution was diluted, the dimer dissociated into monomers which were inactive in tRNA aminoacylation. The aminoacylation was investigated with two isoaccepting tRNAsGly isolated from the posterior silk glands. Transfer RNA1Gly was aminoacylated 2-fold faster than tRNA2Gly. Transfer RNA-binding experiments revealed that tRNA1Gly binds with the enzyme in a molar ratio of 2:1, whereas tRNA2Gly formed a 1:1 complex with the enzyme. Based on these experimental results, we proposed that the Bombyx mori glycyl-tRNA synthetase has two active sites for tRNA aminoacylation and that the number of tRNA molecules bound on the synthetase closely correlates with the velocity of aminoacylation.

Glycyl- and alanyl-tRNA synthetases from Bombyx mori. Purification and properties.

Glycyl- and alanyl-tRNA synthetases have been purified from an extract of Bombyx mori posterior silk glands by a procedure that allows for the simultaneous isolation of both enzymes. Glycyl-tRNA synthetase is a dimer of Mr = 160,000 consisting of similar or identical subunits, whereas alanyl-tRNA synthetase is a monomer of Mr = 110,000 to 115,000. The abundance of these two enzymes in the posterior silk gland is consistent with the observed adaptation of this organ to the production of the silk protein, fibroin. The two enzymes are similar in oligomeric structure to the corresponding enzymes in Saccharomyces cerevisiae, but dissimilar from their counterparts in Escherichia coli.

Glycyl-tRNA synthetase from baker's yeast. Interconversion between active and inactive forms of the enzyme.

Glycyl-tRNA synthetase from baker's yeast has been purified to homogeneity. This synthetase was found to be very sensitive to proteases present in the yeast extracts and to oxidizing agents of thiol groups. In the absence of protease inhibitors and/or dithioerythritol, the enzyme rapidly lost its activity and could not be isolated. The use of these protectors allowed us to obtain different oligomeric structures of the synthetase. In the presence of a minimal concentration of dithioerythritol but in the absence of protease inhibitors, a tetrameric glycyl-tRNA synthetase of the alpha 2 beta 2 type (alpha = 67 600, beta = 57 500) with a very low specific activity was recovered. With high concentrations of both protectors, a dimeric enzyme was isolated with a specific activity comparable to that for other yeast synthetases. The enzyme was of the alpha 2 type where alpha = 70 000--80 000 daltons, depending on whether phenylmethanesulfonyl fluoride or diisopropyl fluorophosphate was used as the protecting agent. The native form of the enzyme (alpha 2 = 160 000) associated easily with other proteins in various complexes of molecular weights from 250 000 to 300 000, some of them containing valyl-tRNA synthetase. The dimeric glycyl-tRNA synthetase was found in equilibrium with its subunits. Diluting the enzyme solution or increasing the salt concentration displaced the equilibrium toward the monomers, which are catalytically inactive for both the tRNA aminoacylation and the PPi-ATP exchange reactions. Addition of both tRNAGly and ATP.MgCl2 plus glycine displaced the equilibrium toward the dimeric form of the enzyme. Thiol groups were found to be involved in the association between the two subunits and in both activities of the synthetase. The results are interpreted in the light of possible regulatory mechanisms of the activity of this synthetase.

Two enzymically active forms of glycyl-tRNA synthetase from Bacillus brevis. Purification and properties.

Using sucrose density centrifugation and gel filtration of a 105000 X g supernatant of Bacillus brevis two enzymic activities of glycyl-tRNA synthetase were separated. Enzyme catalyzing the aminoacylation of tRNA (E1) elutes in a high-molecular-weight region. Enzyme active in glycylhydroxamate formation (E2) elutes from a Sephadex gel column and sediments in sucrose density gradient in a region of relatively low molecular weight. The presence of two enzymic activities does not depend on the method of cell disruption; their proportion does not change when protease inhibitor (diisopropylphosphorofluoridate) is added to the extraction buffer. Both E1 and E2 were purified to a nearly homogeneous state. Sedimentation coefficients (sw,20) were found to be 8.6 S and 3.6 S and molecular weights 226000 and 66000 for E1 and E2, respectively. During storage, E1 dissociates into two components, one of which has electrophoretic mobility identical to E2. The molecular weight of the other component is about 1600000. Electrophoresis of E1 in the presence of sodium dodecylsulfate reveals two bands corresponding to molecular weights of 81000 and 30000. Under these conditions, E2 dissociates into a polypeptide with a molecular weight of 30000. Valine was found to be the N-terminal amino acid for E2 and both valine and glutamic acid were N-terminal amino acids for E1. It is concluded that E1 is a tetrameric protein consisting of two large and two small subunits (alpha2beta2). E2 is a component of E1 with a structural formula alpha2.