Daniel Kern

Factors determining the specificity of the tRNA aminoacylation reaction: Non-absolute specificity of tRNA-aminoacyl-tRNA synthetase recognition and particular importance of the maximal velocity

Summary It is generally believed that the specificity of tRNA aminoacylation results solely from a specific recognition between the aminoacyl-tRNA synthetase and the cognate tRNA. In fact, this specificity is not absolute: this is supported by the following observations (1) the existence of tRNA mischarging in homologous systems under usual aminoacylation conditions, (2) the existence of inhibitions produced by « non-cognatetRNA species in correct aminoacylation reactions, (3) the lack of specificity of AMP- and PPi- independent aminoacyl-tRNA synthetase catalysed deacylation of aminoacyl-tRNA species, (4) the isolation of complexes between aminoacyl-tRNA synthetases and non-cognate tRNA species. The affinities between aminoacyl-tRNA synthetases and non-cognate tRNA species, estimated by the Km measurements in mischarging reactions, have been found only diminished by 1 or 2 orders of magnitude as compared to the values found in specific systems, whereas the Vmax values for mischarging have been found diminished by 3 or 4 orders of magnitude. This suggests that tRNA aminoacylation depends more upon the maximal velocity of the reaction than upon the recognition between aminoacyl-tRNA synthetase and tRNA. Furthermore, we found that the recognition of a tRNA by an aminoacyl-tRNA synthetase does not seem to require the 3′ terminal part of the amino acid acceptor stem. As the importance of this part of the tRNA molecule during the aminoacylation process has been well established, it is possible that it is involved in determining the Vmax of the aminoacylation reaction, probably by positioning the 3′ terminal adenosine in the catalytic site of the enzyme. In conclusion, it appears that the specificity of the tRNA aminoacylation reaction proceeds through two discrimination mechanisms: the first one, measured by the Km, acts at the recognition level; the second one, which is more effective, is measured by the Vmax values. Competition phenomena have been observed between cognate and non-cognate tRNA species. They enhance the specificity of the tRNA aminoacylation, but their contribution to the specificity is low compared to that brought by Km and Vmax. Finally we found that a more rapid enzymatic deacylation of mischarged tRNA species (as compared to correctly charged ones) cannot be considered as a general mechanism for correction of misaminoacylation.

The crystallization of biological macromolecules from precipitates: evidence for Ostwald ripening

Abstract Crystals were obtained by different methods under conditions where nucleation and growth occur from precipitated macromolecular material. The phenomenon was observed with compounds of different size and nature, such as thaumatin, concanavalin A, an α-amylase, a thermostable aspartyl-tRNA synthetase, the nucleo-protein complex between a tRNA Asp transcript and its cognate yeast aspartyl-tRNA synthetase, and tomato bushy stunt virus. In each system, after a rather rapid precipitation step at high supersaturation lasting one to several days, a few microcrystals appear after prolonged equilibration at constant temperature. With α-amylase, the virus and the thermostable synthetase, crystallization is accompanied by appearance of depletion zones around the growing crystals and growth of the largest crystals at the expense of the smaller ones. These features are evidences for crystal growth by Ostwald ripening. In the case of thaumatin, concanavalin A and the nucleo-protein complex, crystallization occurs by a phase transition mechanism since it is never accompanied by the disappearance of the smallest crystals. A careful analysis with thermostable aspartyl-tRNA synthetase indicates that its crystallization at 4°C under high supersaturation starts by a phase transition mechanism with the formation of small crystals within an amorphous protein precipitate. Ostwald ripening follows over a period of up to three/four months with a growth rate of about 0.8 A/s that is 13 times slower than that of crystals growing at 20°C in the absence of precipitate without ripening. At the end of the ripening process at 4°C, only one unique synthetase crystal remains per microassay with dimensions as large as 1 mm.

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.

The role of purification in the crystallization of proteins and nucleic acids

Abstract In structural biology, the crystallization of the macromolecules often represents the most challenging step. Beside classical factors which determine the solubility of macromolecules, purity of compounds is another major parameter governing crystal growth. With aminoacyl-tRNA synthetases and transfer ribonucleic acids as examples, it will be shown that molecules to be crystallized not only have to be pure in terms of contaminating molecules, but also in terms of sequence integrity and conformational homogeneity. A chromatographic method based on salting-out of proteins or nucleic acids on Sepharose 4B gels and back-solubilization with inverse salt gradients will be discussed in the light of crystal growth experiments.

Yeast mitochondrial Gln-tRNA Gln is generated by a GatFAB-mediated transamidation pathway involving Arc1p-controlled subcellular sorting of cytosolic GluRS

It is impossible to predict which pathway, direct glutaminylation of tRNA(Gln) or tRNA-dependent transamidation of glutamyl-tRNA(Gln), generates mitochondrial glutaminyl-tRNA(Gln) for protein synthesis in a given species. The report that yeast mitochondria import both cytosolic glutaminyl-tRNA synthetase and tRNA(Gln) has challenged the widespread use of the transamidation pathway in organelles. Here we demonstrate that yeast mitochondrial glutaminyl-tRNA(Gln) is in fact generated by a transamidation pathway involving a novel type of trimeric tRNA-dependent amidotransferase (AdT). More surprising is the fact that cytosolic glutamyl-tRNA synthetase ((c)ERS) is imported into mitochondria, where it constitutes the mitochondrial nondiscriminating ERS that generates the mitochondrial mischarged glutamyl-tRNA(Gln) substrate for the AdT. We show that dual localization of (c)ERS is controlled by binding to Arc1p, a tRNA nuclear export cofactor that behaves as a cytosolic anchoring platform for (c)ERS. Expression of Arc1p is down-regulated when yeast cells are switched from fermentation to respiratory metabolism, thus allowing increased import of (c)ERS to satisfy a higher demand of mitochondrial glutaminyl-tRNA(Gln) for mitochondrial protein synthesis. This novel strategy that enables a single protein to be localized in both the cytosol and mitochondria provides a new paradigm for regulation of the dynamic subcellular distribution of proteins between membrane-separated compartments.

When contemporary aminoacyl-tRNA synthetases invent their cognate amino acid metabolism

Faithful protein synthesis relies on a family of essential enzymes called aminoacyl-tRNA synthetases, assembled in a piecewise fashion. Analysis of the completed archaeal genomes reveals that all archaea that possess asparaginyl-tRNA synthetase (AsnRS) also display a second ORF encoding an AsnRS truncated from its anticodon binding-domain (AsnRS2). We show herein that Pyrococcus abyssi AsnRS2, in contrast to AsnRS, does not sustain asparaginyl-tRNAAsn synthesis but is instead capable of converting aspartic acid into asparagine. Functional analysis and complementation of an Escherichia coli asparagine auxotrophic strain show that AsnRS2 constitutes the archaeal homologue of the bacterial ammonia-dependent asparagine synthetase A (AS-A), therefore named archaeal asparagine synthetase A (AS-AR). Primary sequence- and 3D-based phylogeny shows that an archaeal AspRS ancestor originated AS-AR, which was subsequently transferred into bacteria by lateral gene transfer in which it underwent structural changes producing AS-A. This study provides evidence that a contemporary aminoacyl-tRNA synthetase can be recruited to sustain amino acid metabolism.

The yeast aminoacyl-tRNA synthetases. Methodology for their complete or partial purification and comparison of their relative activities under various extraction conditions.

Several fractionation steps are described which can be applied to the partial purification of the 20 aminoacyl-tRNA synthetases from commercial bakers yeast. Comparative experiments performed in the presence or absence of protease inhibitors revealed that some enzymes prepared in the presence of the inhibitor exhibit much higher specific activities than the proteins extracted in the absence of the inhibitor. The methodology reported can be used for the simultaneous preparation of several pure aminoacyl-tRNA synthetases. As examples, the large scale purification of phenylalanyl-and valyl-tRNA synthetases are described.

Complete purification and studies on the structural and kinetic properties of two forms of yeast valyl-tRNA synthetase

Two forms of bakers yease valyl-tRNA synthetase have been purified to apparent homogeneity by classical methods. It was demonstrated that one of the two forms of the enzyme originates from the other by proteolysis, the respective amounts of each form depending on the physiological state of the yeast. The species mainly isolated from exponential growing yeast cells is a monomer of 130,000 daltons molecular weight. In stationary phase cells or in commercial yeast the major species is a degraded monomer of 120,000 daltons molecular weight ; however when the purification is carried out in the presence of phenylmethyl-sulphonyl fluoride, or diisopropylfluorophosphate large amounts of the not - degreded monomer can be obtained. Of great practical usefulness is the fact that large amounts of the native enzyme can be obtained pure after only two chromatographic steps on DEAE-cellulose and hydroxylapatite. The kinetic constants for valine, ATP and tRNAVal were determined, as well as the optimum aminoacylation conditions. It was found that the specific activity of the nondegraded valyl-tRNA synthetase is higher than that of the proteolysed enzyme for the aminoacylation reaction. On the contrary, both forms have the same ATP-pyroposphate exchange activity. The amino acids composition of the native enzyme was established. The tryptic fingerprints of the two valyl-tRNA synthetases were studied. Essentially similar maps were obtained. The number of the spots in the fingerprints indicates that the enzymes contain a high proportion of repeated sequences.

Dual-targeted tRNA-dependent amidotransferase ensures both mitochondrial and chloroplastic Gln-tRNAGln synthesis in plants

Aminoacyl-tRNAs are generally formed by direct attachment of an amino acid to tRNAs by aminoacyl-tRNA synthetases, but Gln-tRNA is an exception to this rule. Gln-tRNAGln is formed by this direct pathway in the eukaryotic cytosol and in protists or fungi mitochondria but is formed by an indirect transamidation pathway in most of bacteria, archaea, and chloroplasts. We show here that the formation of Gln-tRNAGln is also achieved by the indirect pathway in plant mitochondria. The mitochondrial-encoded tRNAGln, which is the only tRNAGln present in mitochondria, is first charged with glutamate by a nondiscriminating GluRS, then is converted into Gln-tRNAGln by a tRNA-dependent amidotransferase (AdT). The three subunits GatA, GatB, and GatC are imported into mitochondria and assemble into a functional GatCAB AdT. Moreover, the mitochondrial pathway of Gln-tRNAGln formation is shared with chloroplasts as both the GluRS, and the three AdT subunits are dual-imported into mitochondria and chloroplasts.

Effects of ochratoxin a metabolites on yeast phenylalanyl-tRNA synthetase and on the growth and in vivo protein synthesis of hepatoma cells

The ochratoxin A (OTA) metabolite (4R)-4-hydroxyochratoxin A [4R)-OTA) inhibits the aminoacylation of phenylalanine tRNA catalyzed by phenylalanyl-tRNA synthetase (PheRS) with a Ki-value of 0.9 mM as compared to 1.3 mM for OTA. It also inhibits protein synthesis and cell growth in the same manner as OTA. Ochratoxin alpha (OT alpha) does not affect either protein synthesis or cell growth.