Multienzyme complexes of eukaryotic aminoacyl-tRNA synthetases

Eukaryotic aminoacyl-tRNA synthetases, unlike their prokaryotic counterparts, may occur as high-Mr multienzyme complexes. Recently, successful purification of synthetase complexes makes possible the elucidation of the structural organization of these high-Mr complexes. Although their physiological significance remains unknown, recent studies suggest some possible functional roles for these complexes.     

Interactions of aminoacyl-tRNA synthetases in high-molecular-weight multienzyme complexes from rat liver

The functional interaction of Arg-, Ile-, Leu-, Lys- and Met-tRNA synthetases occurring within the same rat liver multienzyme complex are investigated by examining the enzymes catalytic activities and inactivation kinetics. The Michaelis constants for amino acids, ATP and tRNAs of the dissociated aminoacyl-tRNA synthetases are not significantly different from those of the high-Mr multienzyme complex, except in a few cases where the Km values of the dissociated enzymes are higher than those of the high-Mr form. The maximal aminoacylation velocities of the individual aminoacyl-tRNA synthetases are not affected by the presence of simultaneous aminoacylation by another synthetase occurring within the same multienzyme complex. Site-specific oxidative modification by ascorbate and nonspecific thermal inactivation of synthetases in the purified rat liver 18 S synthetase complex are examined. Lys- and Arg-tRNA synthetases show remarkably parallel time-courses in both inactivation processes. Leu- and Met-tRNA synthetases also show parallel kinetics in thermal inactivation and possibly oxidative inactivation. Ile-tRNA synthetase shows little inactivation in either process. The oxidative inactivation of Lys- and Arg-tRNA synthetases can be reversed by addition of dithiothreitol. These results suggest that synthetases within the same high-Mr complex catalyze aminoacylation reactions independently; however, the stabilities of some of the synthetases in the multienzyme complex are coupled. In particular, the stability of Arg-tRNA synthetase depends appreciably on its association with fully active Lys-tRNA synthetase.     

Origin and evolution of the mitochondrial aminoacyl-tRNA synthetases

Many theories favor a fusion of 2 prokaryotic genomes for the origin of the Eukaryotes, but there are disagreements on the origin, timing, and cellular structures of the cells involved. Equally controversial is the source of the nuclear genes for mitochondrial proteins, although the alpha-proteobacterial contribution to the mitochondrial genome is well established. Phylogenetic inferences show that the nuclearly encoded mitochondrial aminoacyl-tRNA synthetases (aaRSs) occupy a position in the tree that is not close to any of the currently sequenced alpha-proteobacterial genomes, despite cohesive and remarkably well-resolved alpha-proteobacterial clades in 12 of the 20 trees. Two or more alpha-proteobacterial clusters were observed in 8 cases, indicative of differential loss of paralogous genes or horizontal gene transfer. Replacement and retargeting events within the nuclear genomes of the Eukaryotes was indicated in 10 trees, 4 of which also show split alpha-proteobacterial groups. A majority of the mitochondrial aaRSs originate from within the bacterial domain, but none specifically from the alpha-Proteobacteria. For some aaRS, the endosymbiotic origin may have been erased by ongoing gene replacements on the bacterial as well as the eukaryotic side. For others that accurately resolve the alpha-proteobacterial divergence patterns, the lack of affiliation with mitochondria is more surprising. We hypothesize that the ancestral eukaryotic gene pool hosted primordial "bacterial-like" genes, to which a limited set of alpha-proteobacterial genes, mostly coding for components of the respiratory chain complexes, were added and selectively maintained.     

Yeast mitochondrial and cytoplasmic valyl-tRNA synthetases

Yeast mitochondrial tRNA synthetase has been partially purified and chromatographic, catalytic and antigenic properties have been compared to the cytoplasmic homologous enzyme from yeast. No significant differences could be observed between the two enzymes with respect to their behaviour during ammonium sulfate precipitation or in chromatographic separation on DEAE cellulose, hydroxylapatite and Sephadex G 200. The Km of the two enzymes toward tRNAs from yeast mitochondria, yeast cytoplasm or E. coli are pratically identical. The antigenic properties of the two enzymes are very similar; antisera against either the mitochondria or the cytoplasmic enzyme lead to the inhibition of their catalytic properties. The mitochondrial ValRS is formed by a single polypeptide chain whose molecular weight is 125,000 daltons, a value very close to that of the yeast cytoplasmic enzyme.     

Nuclear origin of specific yeast mitochondrial aminoacyl-tRNA synthetases.

Hydroxylapatite chromatographies of mitochondrial and total enzymes from a rho+ yeast, or from the related rho degrees mitochondrial DNA-less mutant, show the occurrence in the mitochondrial enzyme of one Phe-, one Met-, one Leu-tRNA synthetase peak which elutes distinctly from the cytoplasmic counterpart and charges well mitochondrial tRNA, whereas the cytoplasmic enzyme does not. The measurement of the mitochondrial synthetases activities in various enzymatic extracts shows that they are not repressed in rho+ cells grown on 10% glucose and that they are concentrated in the mitochondria (Phe- and Met- tRNA synthetases) but are also present outside the mitochondria. It is concluded that yeast mitochondrial protein biosynthesis involves the nuclear coded mitochondrial specific Phe-, Met- and Leu-tRNA synthetases and that the entrance of the synthetases into the mitochondria needs no factor depending on the mitochondrial DNA.     

Molecular evolution: aminoacyl-tRNA synthetases on the loose

Modified versions - paralogs - of the catalytic domain of at least three different aminoacyl-tRNA synthetases have been found to serve catalytic or regulatory roles in other reactions. These findings suggest that the first modern tRNA-synthetases could have been derived from amino-acid biosynthetic enzymes.     

Macromolecular complexes of aminoacyl-tRNA synthetases from eukaryotes. 1. Extensive purification and characterization of the high-molecular-weight complex(es) of seven aminoacyl-tRNA synthetases from sheep liver.

Starting from homogenates of sheep liver, extensive co-purification of seven aminoacyl-tRNA synthetases to high specific activities was achieved by a three-step procedure involving fractional precipitation by poly(ethylene glycol) 6000, gel filtration on 6% agarose and chromatography on Sepharose-bound tRNA. The purified material is composed of nine major protein components as revealed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and has an apparent molecular weight of about 10(6) estimated by gel filtration on 6% agarose. It contains aminoacyl-tRNA synthetase activities specific for methionine, lysine, arginine, leucine, isoleucine, glutamine and glutamic acid. The rigorous co-elution of these seven enzymes at each chromatographic step suggests, but does not conclusively prove, that they are physically associated within the same complex. The enzyme composition of the high-molecular-weight complex purified from sheep liver is identical to that of the complex previously isolated from human placenta by Denney in 1977 (Arch. Biochem. Biophys. 183, 156--167).     

Handling mammalian mitochondrial tRNAs and aminoacyl-tRNA synthetases for functional and structural characterization

The mammalian mitochondrial (mt) genome codes for only 13 proteins, which are essential components in the process of oxidative phosphorylation of ADP into ATP. Synthesis of these proteins relies on a proper mt translation machinery. While 22 tRNAs and 2 rRNAs are also coded by the mt genome, all other factors including the set of aminoacyl-tRNA synthetases (aaRSs) are encoded in the nucleus and imported. Investigation of mammalian mt aminoacylation systems (and mt translation in general) gains more and more interest not only in regard of evolutionary considerations but also with respect to the growing number of diseases linked to mutations in the genes of either mt-tRNAs, synthetases or other factors. Here we report on methodological approaches for biochemical, functional, and structural characterization of human/mammalian mt-tRNAs and aaRSs. Procedures for preparation of native and in vitro transcribed tRNAs are accompanied by recommendations for specific handling of tRNAs incline to structural instability and chemical fragility. Large-scale preparation of mg amounts of highly soluble recombinant synthetases is a prerequisite for structural investigations that requires particular optimizations. Successful examples leading to crystallization of four mt-aaRSs and high-resolution structures are recalled and limitations discussed. Finally, the need for and the state-of-the-art in setting up an in vitro mt translation system are emphasized. Biochemical characterization of a subset of mammalian aminoacylation systems has already revealed a number of unprecedented peculiarities of interest for the study of evolution and forensic research. Further efforts in this field will certainly be rewarded by many exciting discoveries.     

Non-canonical eukaryotic glutaminyl- and glutamyl-tRNA synthetases form mitochondrial aminoacyl-tRNA in Trypanosoma brucei

Glutaminyl-tRNA synthetase is thought to be absent from organelles. Instead, Gln-tRNA is formed via the transamidation pathway, the other route to this essential compound in protein biosynthesis. However, it was previously shown that glutaminyl-tRNA synthetase activity is present in Leishmania mitochondria. This work identifies genes encoding glutaminyl- and glutamyl-tRNA synthetase in the closely related organism Trypanosoma brucei. Down-regulation of their respective gene products by RNA interference showed that (i) they are essential for the growth of insect stage T. brucei and (ii) they are responsible for essentially all of the glutaminyl- and glutamyl-tRNA synthetase activity detected in both the cytosol and the mitochondria. In vitro aminoacylation experiments with the recombinant T. brucei enzymes and total tRNA confirmed the identity of the two aminoacyl-tRNA synthetases. Interestingly, T. brucei uses the same eukaryotic-type glutaminyl-tRNA synthetase to form mitochondrial and cytosolic Gln-tRNA. The formation of Glu-tRNA in mitochondria and the cytoplasm is catalyzed by a single eukaryotic-type discriminating glutamyl-tRNA synthetase. T. brucei, similar to Leishmania, imports all of its mitochondrial tRNAs from the cytosol. The use of these two eukaryotic-type enzymes in mitochondria may therefore reflect an adaptation to the situation in which the cytosol and mitochondria use the same set of tRNAs.     

Chromatofocusing of aminoacyl-tRNA synthetases, extracted from NMRI mouse liver

Chromatofocusing of 17 aminoacyl-tRNA synthetases extracted from NMRI mouse liver is described and the apparent isoelectric points of these enzymes are presented. Each of 15 aminoacyl-tRNA synthetases was present in two peaks. Isoleucyl-tRNA synthetase showed only one peak and arginyl-tRNA synthetase was present in three peaks. Phosphorylation/dephosphorylation experiments with arginyl-tRNA synthetase indicate that the peaks represent phosphorylated and unphosphorylated synthetase protein. One example of detection of increased protein phosphorylation during a biological experiment is presented.     

Studies on two groups of aminoacyl-tRNA synthetases from rat liver

Aminoacyl-tRNA synthetases from rat-liver cytoplasm were fractionated into two groups, characterized by their sedimentation coefficients of about 20S and 5S, respectively. These two groups of synthetases could be isolated from postmicrosomal supernatant either by gradient centrifugation, by gel filtration or by acid treatment at pH 5.2. Both groups were required for maximal amino acid incorporation in a cell-free system.     

Subcellular distribution and properties of rabbit liver aminoacyl-tRNA synthetases under myocardial ischemia

Subcellular distribution of aminoacyl-tRNA synthetase activities has been studied in normal rabbit liver and under experimental myocardial ischemia (EMI). An increase in the activity of a number of aminoacyl-tRNA synthetases in postmitochondrial and postribosomal supernatants from rabbit liver has been determined 12 hr after EMI. Gel chromatography of the postribosomal supernatant on Sepharose 6B shows that aminoacyl-tRNA synthetase activities are distributed among the fractions with M_r 1.82×10⁶, 0.84×10⁶ (high-M_r aminoacyl-tRNA synthetase complexes) and 0.12–0.35×10⁶. In the case of EMI aminoacyl-tRNA synthetase activities are partly redistributed from the 1.82×10⁶ complex into the 0.84×10⁶ complex. The catalytic properties of both free and complex leucyl-tRNA synthetases have been compared. K_M for all the substrates are the values of the same order in norm and under EMI. A decrease in some aminoacyl-tRNA synthetase activities associated with polyribosomes has been observed 12 hr after EMI. The interaction of aminoacyl-tRNA synthetases with polyribosomes stimulates the catalytic activity of some enzymes and protects them from heat inactivationin vitro. It is assumed that the changes in association of aminoacyl-tRNA synthetases with high-M_r complexes and compartmentalization of these enzymes on polyribosomes may be related to the alteration of protein biosynthesis under myocardial ischemia.     

Occurrence of 5SrRNA in high molecular weight complexes of aminoacyl-tRNA synthetases in a rat liver supernatant.

The 5SrRNA in the rat liver postmicrosomal supernatant was investigated. Acrylamide gel electrophoresis and Northern blot analysis showed that most of the 5SrRNA was present in the fractions obtained on high molecular weight regions separated by Sephadex G-200 column chromatography of the supernatant, which contained the bulk of the methionyl-tRNA synthetase (Fraction I) and tyrosyl-tRNA synthetase (Fraction II). A high molecular weight complex containing nine aminoacyl-tRNA synthetases [Mirande, M., LeCorre, D., & Waller, J.-P. (1985) Eur. J. Biochem. 147, 281-289] was purified by fractional precipitation with polyethylene glycol 6000, gel filtration on Bio-Gel A-1.5m, and finally tRNA-Sepharose column chromatography, which gave two fractions. Fraction B showed the activities of nine aminoacyl-tRNA synthetases and gave protein bands corresponding to eight previously identified enzymes on SDS-PAGE. Fraction A, eluted with a lower KCl concentration than Fraction B, showed lower activities than fraction B of eight of the aminoacyl-tRNA synthetases, the exception being prolyl-tRNA synthetase. The staining patterns with ethidium bromide of the RNAs after PAGE showed 5SrRNA bands for Fraction A but not for Fraction B. However, Northern blot analysis indicated that 5SrRNA was present in both Fractions A and B. The staining pattern after SDS-PAGE of Fraction A with Coomassie Brilliant Blue showed several protein bands in addition to those observed for Fraction B, one of which, with a staining intensity comparable with those of other bands, was located at the same position as ribosomal protein L5, which is the protein moiety of the 5SrRNA-L5 protein complex of ribosomal 60S subunits.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sedimentation behaviour of aminoacyl-tRNA synthetases from mixed lysates of yeast and rabbit liver

The subcellular distribution of five aminoacyl-tRNA synthetases from yeast, including lysyl-, arginyl- and methionyl-tRNA synthetases known to exist as high-molecular-weight complexes in lysates from higher eukaryotes, was investigated. To minimize the risks of proteolysis, spheroplasts prepared from exponentially grown yeast cells were lysed in the presence of several proteinase inhibitors, under conditions which preserved the integrity of the proteinase-rich vacuoles. The vacuole-free supernatant was subjected to sucrose density gradient centrifugation. No evidence for multimolecular associations of these enzymes was found. In particular, phenylalanyl-tRNA synthetase activity was not associated with the ribosomes, whereas purified phenylalanyl-tRNA synthetase from sheep liver, added to the yeast lysate prior to centrifugation, was entirely recovered in the ribosomal fraction. A mixture of lysates from yeast and rabbit liver was also subjected to sucrose gradient centrifugation and assayed for methionyl- and arginyl-tRNA synthetase activities, under conditions which allowed discrimination between the enzymes originating from yeast and rabbit. The two enzymes from rabbit liver were found to sediment exclusively as high-molecular-weight complexes, in contrast to the corresponding enzymes from yeast, which displayed sedimentation properties characteristic of free enzymes. The preservation of the complexed forms of mammalian aminoacyl-tRNA synthetases upon mixing of yeast and rabbit liver extracts argues against the possibility that failure to observe complexed forms of these enzymes in yeast was due to uncontrolled proteolysis. Furthermore, this result denies the presence, in the crude extract from liver, of components capable of inducing artefactual aggregation of the yeast aminoacyl-tRNA synthetases, and thus indirectly argues against an artefactual origin of the multienzyme complexes encountered in lysates from mammalian cells.