The developmental biochemistry of cotton seed embryogenesis and germination. VI. Levels of cytosol and chloroplast aminoacyl-tRNA synthetases during cotyledon development.

The separation of isotransferring aminoacyl-tRNA synthetase activities (amino acid: tRNA ligases, EC 6.1.1.x) for several amino acids extracted from tissues of embryonic and germinating cotton seeds was carried out by DEAE-cellulose column chromatography. Evidence was obrained that the separated activities represent discrete enzymes, and could be defined as cytosol or chloroplast enzymes by several criteria. The levels of the cytosol enzymes per cell were found to be constant in germinated and ungerminated cotyledons. Chloroplast enzymes were found to be present in immature embryonic cotyledons and in roots at constant levels relative to the cytosol enzymes, but found to increase markedly in germinating cotyledons. This increase takes place to the same extent in etiolated cotyledons as in greened cotyledons indicating that the chloroplast synthetase increase is analogous to the simultaneous increase in chloroplast tRNA and rRNA which also is not light dependent. The separated cytosol and chloroplast enzymes show varying degrees of specificity for isoaccepting tRNA species from homologous and heterologous sources.     

Regulation of synthesis of the branched-chain amino acids and cognate aminoacyl-transfer ribonucleic acid synthetases of Escherichia coli: a common regulatory element

Regulation of isoleucine, valine, and leucine biosynthesis and isoleucyl-, valyl-, and leucyl-transfer ribonucleic acid (tRNA) synthetase formation was examined in two mutant strains of Escherichia coli. One mutant was selected for growth resistance to the isoleucine analogue, ketomycin, and the other was selected for growth resistance to both trifluoroleucine and valine. Control of the synthesis of the branched-chain amino acids by repression was altered in both of these mutants. They also exhibited altered control of formation of isoleucyl-tRNA synthetase (EC 6.1.15, isoleucine:sRNA ligase, AMP), valyl-tRNA synthetase (EC 6.1.1.9, valine:sRNA ligase, AMP), and leucyl-tRNA synthetase (EC 6.1.1.4, leucine:sRNA ligase, AMP). These results suggest the existence of a common element for the control of these two classes of enzymes in Escherichia coli.     

Evidence for the Existence of Two Arginyl-Transfer Ribonucleic Acid Synthetase Activities in Escherichia coli

Two arginyl-transfer ribonucleic acid (tRNA) synthetase (EC 6.1.1.13, arginine: ribonucleic acid ligase adenosine monophosphate) activities were found in extracts of Escherichia coli strains AB1132 and NP2. The two arginyl-tRNA synthetase activities in extracts of strain AB1132 were found to be separable by diethylaminoethyl-cellulose column chromatography, Sephadex column fractionation, and by sucrose density gradient centrifugation. In addition, in the standard assay using extracts of strain AB1132 there were two pH optima for arginyl-tRNA synthetase activity. Furthermore, when arginyl-tRNA synthetase of strain NP2 was fractionated by hydroxylapatite column chromatography, two activities were observed which were similar to those of strain AB1132.     

Variations in activity of aminoacyl-tRNA synthetases as a function of development in Bacillus subtilis

Extracts from Bacillus sublilis cells at various stages of growth and spores were assayed for aminoacyl-tRNA synthetase and methionyl-tRNA transformylase activity. There was no major change in any synthetase activity or in methionyl-tRNA transformylase activity during the sporulation cycle, which implies that these are not sporulation induced enzymes. However, extracts from B. subtilis cultures showed a burst of activity of aminoacyl-tRNA synthetases during exponential growth.Preparations from dormant spores possessed the same kinds of aminoacyl-tRNA synthetase activities as vegetative cells for all the amino acids which were studied. Spores also contained methionyl-tRNA transformylases. These findings suggest that spores ought to be able to aminoacylate tRNA and formylate the initiator. N-formylmethionyl-tRNA, immediately upon germination.     

Non-essential role of lysine residues for the catalytic activities of aspartyl-tRNA synthetase and comparison with other aminoacyl-tRNA synthetases

Essential lysine residues were sought in the catalytic site of baker's yeast aspartyl-tRNA synthetase (an alpha 2 dimer of Mr 125,000) using affinity labeling methods and periodate-oxidized adenosine, ATP, and tRNA(Asp). It is shown that the number of periodate-oxidized derivatives which can be bound to the synthetase via Schiff's base formation with epsilon-NH2 groups of lysine residues exceeds the stoichiometry of specific substrate binding. Furthermore, it is found that the enzymatic activities are not completely abolished, even for high incorporation levels of the modified substrates. The tRNA(Asp) aminoacylation reaction is more sensitive to labeling than is the ATP-PPi exchange one; for enzyme preparations modified with oxidized adenosine or ATP this activity remains unaltered. These results demonstrate the absence of a specific lysine residue directly involved in the catalytic activities of yeast aspartyl-tRNA synthetase. Comparative labeling experiments with oxidized ATP were run with several other aminoacyl-tRNA synthetases. Residual ATP-PPi exchange and tRNA aminoacylation activities measured in each case on the modified synthetases reveal different behaviors of these enzymes when compared to that of aspartyl-tRNA synthetase. When tested under identical experimental conditions, pure isoleucyl-, methionyl-, threonyl- and valyl-tRNA synthetases from E. coli can be completely inactivated for their catalytic activities; for E. coli alanyl-tRNA synthetase only the tRNA charging activity is affected, whereas yeast valyl-tRNA synthetase is only partly inactivated. The structural significance of these experiments and the occurrence of essential lysine residues in aminoacyl-tRNA synthetases are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-molecular-weight forms of aminoacyl-tRNA synthetases and tRNA modification enzymes in Escherichia coli.

The presence of high-molecular-weight complexes of aminoacyl-tRNA synthetases in Escherichia coli has been reported (C. L. Harris, J. Bacteriol. 169:2718-2723, 1987). In the current study, Bio-Gel A-5M gel chromatography of 105,000 x g supernatant preparations from E. coli Q13 indicated high molecular weights for both tRNA methylase (300,000) and tRNA sulfurtransferase (450,000). These tRNA modification enzymes did not appear to exist in the same multienzymic complex. On the other hand, 4-thiouridine sulfurtransferase eluted with aminoacyl-tRNA synthetase activity on Bio-Gel A-5M, and both of these activities were cosedimented after further centrifugation of cell supernatants at 160,000 x g for 18 h. Despite this evidence for association of the sulfurtransferase with the synthetase complex, isoleucyl-tRNA synthetase and tRNA sulfurtransferase were totally resolved from each other by DEAE-Sephacel chromatography. Subsequent gel chromatography showed little change in their elution positions on agarose. Hence, either nonspecific aggregation occurred here, or the modification enzymes studied are not members of the aminoacyl-tRNA synthetase complex in E. coli. These findings do suggest that some bacterial tRNA modification enzymes are present in multiprotein complexes of high molecular weight.     

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。     

Initial position of aminoacylation of individual Escherichia coli, yeast, and calf liver transfer RNAs.

Transfer RNAs from Escherichia coli, yeast (Sacharomyces cerevisiae), and calf liver were subjected to controlled hydrolysis with venom exonuclease to remove 3'-terminal nucleotides, and then reconstructed successively with cytosine triphosphate (CTP) and 2'- or 3'-deoxyadenosine 5'-triphosphate in the presence of yeast CTP(ATP):tRNA nucleotidyltransferase. The modified tRNAs were purified by chromatography on DBAE-cellulose or acetylated DBAE-cellulose and then utilized in tRNA aminoacylation experiments in the presence of the homologous aminoacyl-tRNA synthetase activities. The E. coli, yeast, and calf liver aminoacyl-tRNA synthetases specific for alanine, glycine, histidine, lysine, serine, and threonine, as well as the E. coli and yeast prolyl-tRNA synthetases and the yeast glutaminyl-tRNA synthetase utilized only those homologous modified tRNAs terminating in 2'-deoxyadenosine (i.e., having an available 3'-OH group). This is interpreted as evidence that these aminoacyl-tRNA synthetases normally aminoacylate their unmodified cognate tRNAs on the 3'-OH group. The aminoacyl-tRNA synthetases from all three sources specific argining, isoleucine, leucine, phenylalanine, and valine, as well as the E. coli and yeast enzymes specific for methionine and the E. coli glutamyl-tRNA synthetase, used as substrates exclusively those tRNAs terminating in 3'-deoxyadenosine. Certain aminoacyl-tRNA synthetases, including the E. coli, yeast, and calf liver asparagine and tyrosine activating enzymes, the E. coli and yeast cysteinyl-tRNA synthetases, and the aspartyl-tRNA synthetase from yeast, utilized both isomeric tRNAs as substrates, although generally not at the same rate. While the calf liver aspartyl- and cysteinyl-tRNA synthetases utilized only the corresponding modified tRNA species terminating in 2'-deoxyadenosine, the use of a more concentrated enzyme preparation might well result in aminoacylation of the isomeric species. The one tRNA for which positional specificity does seem to have changed during evolution is tryptophan, whose E. coli aminoacyl-tRNA synthetase utilized predominantly the cognate tRNA terminating in 3'-deoxyadenosine, while the corresponding yeast and calf liver enzymes were found to utilize predominantly the isomeric tRNAs terminating in 2'-deoxyadenosine. The data presented indicate that while there is considerable diversity in the initial position of aminoacylation of individual tRNA isoacceptors derived from a single source, positional specificity has generally been conserved during the evolution from a prokaryotic to mammalian organism.     

Close linkage of the genes serC (for phosphohydroxy pyruvate transaminase) and serS (for seryl-transfer ribonucleic acid synthetase) in Escherichia coli K-12

Escherichia coli strain K28, isolated after nitrosoguanidine mutagenesis, was found to be auxotrophic for serine. It was also temperature sensitive for growth as a result of producing an altered seryl-transfer ribonucleic acid (tRNA) synthetase (EC 6.1.1.11, l-serine: tRNA ligase [AMP]). The auxotrophy was caused by a mutation in the structural gene for phosphohydroxy-pyruvate transaminase (serC), which was distinct from, but closely linked to, the structural gene for seryl-tRNA synthetase (serS). We conclude that the relevant genes are in the order gal-serS-serC-aroA.     

Selective 32P-labelling of individual species in a total tRNA population.

A simple procedure to label individual tRNA species in a total tRNA preparation has been developed. The principle of the method is as follows: total crude tRNA (from E. coli) is incubated in the presence of a crude aminoacyl-tRNA synthetase preparation, containing most aminoacyl-tRNA synthetases and only one specific amino acid corresponding to the tRNA species which is intended to be labelled. This achieves the purpose of charging the desired tRNA species thereby protecting its 3'OH-terminus; obviously all the other tRNA species will have a free 3'OH group. Periodate oxidation, followed by beta-elimination, destroys any free 3'OH. After deacylation of the specific aminoacylated tRNA at pH 8.8 the only free 3'OH group will be the one of the desired tRNA species. High specific activity (32P)-pCp is ligated to this 3'OH by means of T4-RNA ligase. Two-dimensional polyacrylamide gel electrophoresis (2D-PGE) and sequence analysis of the isolated tRNA show that the method is very specific. Individually labelled tRNA species can be used as probes for cloning tRNA genes.     

Evidence for unfolding of the single-stranded GCCA 3'-End of a tRNA on its aminoacyl-tRNA synthetase from a stacked helical to a foldback conformation

The conformation of a tRNA in its initial contact with its cognate aminoacyl-tRNA synthetase was investigated with the Escherichia coli glutamyl-tRNA synthetase-tRNA(Glu) complex. Covalent complexes between the periodate-oxidized tRNA(Glu) and its synthetase were obtained. These complexes are specific since none were formed with any other oxidized E. coli tRNA. The three major residues cross-linked to the 3'-terminal adenosine of oxidized tRNA(Glu) are Lys115, Arg209, and Arg48. Modeling of the tRNA(Glu)-glutamyl-tRNA synthetase based on the known crystal structures of Thermus thermophilus GluRS and of the E. coli tRNA(Gln)-glutaminyl-tRNA synthetase complex shows that these three residues are located in the pocket that binds the acceptor stem, and that Lys115, located in a 26 residue loop closed by coordination to a zinc atom in the tRNA acceptor stem-binding domain, is the first contact point of the 3'-terminal adenosine of tRNA(Glu). In our model, we assume that the 3'-terminal GCCA single-stranded segment of tRNA(Glu) is helical and extends the stacking of the acceptor stem. This assumption is supported by the fact that the 3' CCA sequence of tRNA(Glu) is not readily circularized in the presence of T4 RNA ligase under conditions where several other tRNAs are circularized. The two other cross-linked sites are interpreted as the contact sites of the 3'-terminal ribose on the enzyme during the unfolding and movement of the 3'-terminal GCCA segment to position the acceptor ribose in the catalytic site for aminoacylation.     

Control of Arginine Biosynthesis in Escherichia coli: Role of Arginyl-Transfer Ribonucleic Acid Synthetase in Repression

The physiological role of arginyl-transfer ribonucleic acid (Arg-tRNA) synthetase (E.C. 6.1.1.13, arginine: RNA ligase adenosine monophosphate) in repression of arginine biosynthetic enzymes was examined. Mutants with nonrepressible synthesis of arginine biosynthetic enzymes were isolated from various strains of Escherichia coli by resistance to growth inhibition by canavanine, an arginine analogue. These mutants possessed reduced Arg-tRNA synthetase activities which were qualitatively different from the synthetase activity of the wild type. The mutant enzymes exhibited turnover in vivo and were less stable in vitro than the wild type at both 4 C and 40 C; they possessed different affinities for both arginine and canavanine as measured by the three common assay systems for aminoacyl-tRNA synthetases. Furthermore, in one case it was shown that (i) the mutant possesed unaltered uptake of arginine, and (ii) that the mutant possessed diminished ability to incorporate canavanine into proteins and to attach canavanine to tRNA. These observations suggested that the mutation to canavanine resistance involved a structural change in Arg-tRNA synthetase. Likewise, the results of genetic experiments suggested that the mutants differed from the wild-type strain at only one locus, and that this lies in the region of the chromosomes that includes a structural gene for Arg-tRNA synthetase. It appears that Arg-tRNA synthetase may be involved in some way in repression by arginine of its own biosynthetic enzymes.     

Affinity chromatography of rat liver aminoacyl-tRNA synthetase complex

The affinity column lysyldiaminohexyl-Sepharose 4B has been synthesized for the purification of aminoacyl-tRNA synthetase complexes. Lysyl-tRNA synthetase (EC 6.1.1.6) bound specifically to the Sepharose-bound lysine. The purified lysyl-tRNA synthetase was associated with arginyl-tRNA synthetase (EC 6.1.1.16) and sedimented at 18S and 12S. A 24S lysyl-tRNA synthetase bound specifically to the affinity column and also found associated with arginyl-tRNA synthetase. The results favor the model of a heterotypic multienzyme complex of mammalian aminoacyl-tRNA synthetases.     

Inhibition of Arginyl-Transfer Ribonucleic Acid Synthetase Activity of Escherichia coli by Arginine Biosynthetic Precursors

The arginine biosynthetic precursors, ornithine, citrulline, and argininosuccinate, inhibit arginyl-transfer ribonucleic acid (tRNA) synthetase (EC 6.1.1.13, arginine: soluble RNA ligase, adenosine monophosphate) activity in the in vitro attachment assay system. Ornithine is the most potent, argininosuccinate is next, and citrulline is least effective. The implications of these results are discussed in relation to arginyl-tRNA synthetase activity and the level of the arginine biosynthetic enzymes during conditions of restricted and unrestricted supply of arginine to cells.     

Properties and developmental roles of the lysyl- and tryptophanyl-transfer ribonucleic acid synthetases of Bacillus subtilis: common genetic origin of the corresponding spore and vegetative enzymes

The lysyl-transfer ribonucleic acid synthetase (LRS) and tryptophanyl-transfer ribonucleic acid synthetases (TRS) (l-lysine:tRNA ligase [AMP], EC 6.1.1.6; and l-tryptophan:tRNA ligase [AMP], EC 6.1.1.2) have been purified 60- and 100-fold, respectively, from vegetative cells and spores of Bacillus subtilis. There are no significant differences between the corresponding spore and vegetative enzymes with respect to their elution characteristics from columns of phosphocellulose or hydroxylapatite, their molecular weight (~130,000 for LRS and ~87,000 for TRS as determined by gel filtration), their kinetic constants for substrates (in the amino acid-dependent adenosine triphosphate-pyrophosphate exchange reaction), and the kinetics of inactivation by heat and by antibody. The Mg(2+) requirement for optimal enzyme activity of the corresponding spore and vegetative enzyme differ slightly. Mutants having defective (temperature sensitive) vegetative LRS or TRS activities produce spores in which these enzymes are also defective. The mutant spores are more heat sensitive than the parental type, but contain normal levels of dipicolinic acid. They germinate normally at the restrictive temperature (43 C), but are blocked at specific developmental stages in outgrowth. No modification in temperature sensitivity phenotype occurs during outgrowth, nor is there a change in molecular weight of the two enzymes. The implication is that the LRS and TRS activities of the vegetative and spore stages are each coded (at least in part) by the same structural gene. The temperature sensitivity of mutant spores is discussed with respect to those factors which are involved in the formation of the heat-resistant state.     

Role of Isoleucyl-Transfer Ribonucleic Acid Synthetase in Ribonucleic Acid Synthesis and Enzyme Repression in Yeast

Temperature-sensitive mutations in the isoleucyl-transfer ribonucleic acid (tRNA) synthetase of yeast, ilS(-)1-1 and ilS(-)1-2, were used to examine the role of aminoacyl-tRNA synthetase enzymes in the regulation of ribonucleic acid (RNA) synthesis and enzyme synthesis in a eucaryotic organism. At the permissive temperature, 70 to 100% of the intracellular isoleucyl-tRNA was charged in mutants carrying these mutations; at growth-limiting temperatures, less than 10% was charged with isoleucine. Other aminoacyl-tRNA molecules remained essentially fully charged under both conditions. Net protein and RNA syntheses were rapidly inhibited when the mutant was shifted from the permissive to the restrictive temperature. Most of the ribosomes remained in polyribosome structures at the restrictive temperature even though protein synthesis was strongly inhibited. Two of the enzymes of isoleucine biosynthesis, threonine deaminase and acetohydroxyacid synthetase, were derepressed about twofold during slow growth of the mutants at a growth-limiting temperature. This is about the same degree of derepression that is achieved by growth of an auxotroph on limiting isoleucine. We conclude that charged aminoacyl-tRNA is essential for RNA synthesis and for the multivalent repression of the isoleucine biosynthetic enzymes. Aminoacyl tRNA synthetase enzymes appear to play important regulatory roles in the cell physiology of eucaryotic organisms.     

Temperature-induced derepression of tryptophan biosynthesis in a tryptophanyl-transfer ribonucleic acid synthetase mutant of Bacillus subtilis

A tryptophanyl-transfer ribonucleic acid (tRNA) synthetase (l-tryptophan: tRNA ligase adenosine monophosphate, EC 6.1.1.2) mutant (trpS1) of Bacillus subtilis is derepressed for enzymes of the tryptophan biosynthetic pathway at temperatures which reduce the growth rate but still allow exponential growth. Derepression of anthranilate synthase in a tryptophan-supplemented medium (50 mug/ml) is maximal at 36 C, and the differential rate of synthesis is 600- to 2,000-fold greater than that of the wild-type strain or trpS1 revertants. A study of the derepression pattern in the mutant and its revertants indicates that the 5-fluorotryptophan recognition site of the tryptophanyl-tRNA synthetase is an integral part of the repression mechanism. Evidence for a second locus, unlinked to the trpS1 locus, which functions in the repression of tryptophan biosynthetic enzymes is presented.     

Biochemical and genetic characterization of a temperature-sensitive, tryptophanyl-transfer ribonucleic acid synthetase mutant of Bacillus subtilis

A temperature-sensitive, 5-fluorotryptophan (5FT)-resistant mutant of Bacillus subtilis was isolated which forms an altered tryptophanyl transfer ribonucleic acid synthetase [l-tryptophan: sRNA ligase (AMP), EC 6.1.1.2]. The mutant grows well at 30 C but not at 42 C. At the latter temperature, protein and ribonucleic acid (RNA) synthesis are abolished while deoxyribonucleic acid (DNA) synthesis proceeds for a considerable time. Tryptophanyl-transfer RNA (tRNA) synthetase activity is not detectable in the extracts of the mutant grown at 30 C whether this activity is measured by the attachment of l-tryptophan to tRNA or the l-tryptophan-dependent exchange of (32)P-pyrophosphate with adenosine triphosphate. Mixing experiments with extracts from the wild type and the mutant have ruled out the presence of an inhibitor or the absence of an activator as possible causes. Attempts to retrieve enzyme activity in vitro by various means (different conditions for cell disruption, addition of l-tryptophan, and adenosine triphosphate to the extraction buffer containing glycerol) were unsuccessful. The mutation in the locus of the tryptophanyl tRNA synthetase (trpS) was mapped on the bacterial chromosome by transformation and transduction. It is located between argC and metA. All temperature-resistant transformants recover wild-type levels of tryptophanyl tRNA synthetase activity and sensitivity to 5FT. Spontaneous revertants to temperature resistance are 5FT sensitive, but their levels of tryptophanyl tRNA synthetase activity and the thermolability of this enzyme in cell-free extracts varies. These revertants do not support the growth of a presumed nonsense mutant of phase SPO-1. Transduction experiments with phage PBS-1 indicated that reversion must be the result of an event at the site of the original mutation or at a site extremely close to it.     

Effects of liver regeneration on tRNA contents and aminoacyl-tRNA synthetase activities and sedimentation patterns.

The tRNA content and aminoacyl-tRNA synthetases of regenerating liver in the phase of rapid growth were compared with those of livers from both intact and sham-operated rats. At 48 h after hepatectomy, the amount of active tRNA (called 'total acceptor capacity') is significantly higher in regenerating liver than in control livers, owing to a general, possibly not uniform, increase in the various tRNA families, which suggests that it may contribute to the increased protein synthesis and to decreased protein degradation as well. The activities of most, but not of all, aminoacyl-tRNA synthetases in cell sap of regenerating liver tend to be greater than normal. Increased activity of histidyl-tRNA synthetase fits in with the possibility that the mechanisms that control the rate of protein degradation through aminoacylation of tRNAHis in cultured cells [Scornik (1983) J. Biol. Chem. 258, 882-886] also operate in the liver and play a role in regeneration. Sedimentation analysis of cell sap in sucrose density gradients shows a shift of prolyl-tRNA synthetase activity toward the high-Mr form in regenerating liver. This change might be related to the positive protein balance and to growth in vivo, since it is also observed in the anaplastic Yoshida ascites hepatoma AH 130.