A Neutron Scattering Study of the Ternary Complex EF-Tu•GTP-valy1-tRNAVal 1A

Abstract

The complex formation between elongation factor Tu (EF-Tu), GTP, and valyl-tRNA^Val _1A has been investigated in a hepes buffer of “pH” 7.4 and 0.2 M ionic strength using the small-angle neutron scattering method at concentrations of D₂O where EF-Tu (42% D₂O) and tRNA (71% D₂O) are successively matched by the solvents. The results indicate that EF-Tu undergoes a conformational change and contracts as a result of the complex formation, since the radius of gyration decreases by 15% from 2.82 to 2.39 nm. tRNA^Val _1A, on the other hand, seems to mainly retain its conformation within the complex, since the radii of gyration for the free (after correction for interparticular scattering) and complexed form are essentially the same. 2.38 and 2.47 nm, respectively.     

Antico-operative binding of initiator transfer RNAMet to methionyl-transfer RNA synthetase from Escherichia coli: neutron scattering studies.

The interaction of methionyl-tRNA synthetase with initiator tRNA^Met has been investigated by neutron scattering. On the basis of parallel fluorescence measurements, two types of titrations have been performed. (1) In the presence of 10 mm-MgCl₂, a condition which insures antico-operative binding of two tRNA molecules to the enzyme dimer. (2) With saturating amounts of 5′-AMP and l-methioninol, in the presence of 50 mm-MgCl₂, conditions which allow two transfer RNA molecules to bind the dimer with very similar affinities.Varying the solvent density (²H₂O fraction) in the samples has allowed the identification by neutron scattering of changes in the radius of gyration and in the degree of dissociation of the enzyme dimer upon tRNA binding. In buffer containing 10 mm-MgCl₂, at each contrast studied, the binding process involves two steps. Firstly, one tRNA^met_f molecule binds easily to one dimeric enzyme molecule with an associated decrease of the radius of gyration of the enzyme moiety. The centre of mass of this tRNA lies very close to the centre of mass of the protomer with which it associates. Then, at higher tRNA concentration, a second tRNA molecule binds to the enzyme. However, the affinity of this second site is very much weaker. With the binding of the second tRNA, the radius of gyration of the enzyme moiety increases markedly. Concomitant limited dissociation of the dimer is suggested by the experimental data. These observations combined with the fact that, in 50 mm-MgCl₂ both the increased radius of gyration and the partial dissociation of the enzyme are accomplished in the absence of tRNA and remain unaffected upon binding one or two tRNA, confirm that the hindrance to binding a second tRNA in 10 mm-MgCl₂ arises from the constrained conformation of the one tRNA-enzyme complex.     

Tritium exchange studies of transfer RNA in native and denaturated conformations

Tritium exchange was used as a probe of transfer RNA structure in experiments with unfractionated tRNA (tRNA^Unfrac and homogeneous tRNA₃^Leu from bakers' yeast. Exchange kinetics were measured over a range of ionic conditions that vary in ability to stabilize the secondary and tertiary structure of tRNA. The native conformations of both samples show the same kinetics of exchange. The kinetics for tRNA₃^Leu trapped in a denatured state in a “native” solvent are much faster, reflecting the conformation and not the ionic medium. In 0.1 M-Na⁺, where tRNA₃^Leu is denatured, the kinetics for tRNA^Unfrac are intermediate between those for native and denatured tRNA₃^Leu, suggesting that in this solvent at 0 °C some tRNAs are denatured whereas other are still native. Upon further lowering of Na⁺ concentration, tRNA^Unfrac shows increasingly faster exchange, suggesting complete electrostatic denaturation of the tertiary structure of all the tRNAs in the sample, and even disruption of secondary structure.Extrapolation of the essentially linear early-time kinetics to zero time provides minimal estimates of the number of slowly exchanging hydrogens. For native tRNA₃^Leu the number is 111±2 hydrogens, whereas for the trapped denatured conformation it is only 95±2. This difference reflects a smaller number of hydrogen-bonded bases in the denatured conformation. In 1 M-Na⁺, 101±2 slowly exchanging hydrogens are found for the native tRNA₃^Leu conformation, suggesting an incompletely formed native structure. For native tRNA^Unfrac the comparable number is 101±3. These numbers of slowly exchanging hydrogens in the native conformations are consistent with tertiary structural hydrogen-bonding. Furthermore, this tertiary structure must be responsible for the slower exchange by native tRNA. The observed numbers of exchangeable hydrogens provide a basis for comparison of hydrogen-bonding interactions in native and denatured tRNA conformations.The mechanism of renaturation was also investigated, using tritium exchange as a monitor of perturbation of base pairing during the transition. When tRNA^Unfrac in low Na⁺ is renatured by addition of Mg²⁺ during tritium exchangeout, a burst of exchange or “spillage” of tritium is detected. This suggests that a fraction of the base pairs of the rapidly renaturing tRNAs in the mixture is disrupted during renaturation. In that event, and by analogy with tRNA₃^Leu, part of the base-pairing arrangement of the denatured conformations may not be preserved in the native state; and if the native conformation includes the full “cloverleaf” pattern of secondary structure, that pattern may not be intact in some denatured conformations.     

Sizes of two amino acyl-tRNA synthetase complexes from E. coli with their cognate tRNAs.

The complexes of valyl-tRNA synthetase with tRNA_I^Val and arginyl-tRNA synthetase with tRNA_II^Arg from $\text{E. coli}$ were studied by light scattering measurements and analytical ultracentrifugation of concentrations as low as 40 μg/ml. The molecular weights determined from these studies were 260,000 ± 2,000 for the valyl-tRNA synthetase·tRNA complex, and 310,000 ± 1,500 for the arginyl-tRNA synthetase·tRNA complex at pH 7.1. The stoichiometry for the complexes are apparently 2:1 for valyl-tRNA synthetase and tRNA and 4:1 in the case of the arginyl-tRNA synthetase and tRNA. From the angular dependence of the scattered intensity a radius of gyration of 54.5 Å for the complex between valyl-tRNA synthetase and tRNA was found, whereas for the other complex a value of 59.1 Å was found.     

Neutron scattering studies of escherichia coli tyrosyl-trna synthetase and of its interaction with trna tyr

Small-angle neutron scattering studies of Escherichia coli tyrosyl-tRNA synthetase indicate that in solution this enzyme is a dimer of M_r, 91 (±6) × 10³ with a radius of gyration R_G of 37.8 ± 1.1 Å.The increase in the scattering mass of the enzyme upon binding tRNA^Tyr has been followed in 20 mm-imidazole · HCl (pH 7.6), 10 mm-MgCl₂, 0.1 mm-EDTA, 10 mm-2-mercaptoethanol, 150 mm-KCl. A stoichiometry of one bound tRNA per dimeric enzyme molecule was found. The R_G of the complex is equal to 41 ± 1 Å. Titration experiments in 74% ²H₂O, close to the matching point of tRNA, show an R_G of 38.5 ± 1 Å for the enzyme moiety in the complex. From these values, a minimum distance of 49 Å between the centre of mass of the bound tRNA and that of the enzyme was calculated.In low ionic strength conditions (20 mm-imidazole-HCl (pH 7.6), 10 mm-MgCl₂, 0.1 mm-EDTA, 10 mm-2-mercaptoethanol) and at limiting tRNA concentrations with respect to the enzyme, titrations of the enzyme by tRNA^Tyr are characterized by the appearance of aggregates, with a maximum scattered intensity at a stoichiometry of one tRNA per two enzyme molecules. At this point, the measured M_r and R_G values are compatible with a compact 1:2, tRNA: enzyme complex. This complex forms with a remarkably high stability constant: (enzyme:tRNA:enzyme)/(enzyme:tRNA)(enzyme) of 0.1 to 0.3(× 10⁶) m^?1 (at 20 °C). Upon addition of more tRNA, the complex dissociates in favour of the 1:1, enzyme:tRNA complex, which has a higher stability constant (1 to 3 (× 10⁶) m^?1).     

The yfiC gene of E. coli encodes an adenine-N6 methyltransferase that specifically modifies A37 of tRNA1Val(cmo5UAC)

Transfer RNA is highly modified. Nucleotide 37 of the anticodon loop is represented by various modified nucleotides. In Escherichia coli, the valine-specific tRNA (cmo⁵UAC) contains a unique modification, N⁶-methyladenosine, at position 37; however, the enzyme responsible for this modification is unknown. Here we demonstrate that the yfiC gene of E. coli encodes an enzyme responsible for the methylation of A37 in tRNA₁^Val. Inactivation of yfiC gene abolishes m⁶A formation in tRNA₁^Val, while expression of the yfiC gene from a plasmid restores the modification. Additionally, unmodified tRNA₁^Val can be methylated by recombinant YfiC protein in vitro. Although the methylation of m⁶A in tRNA₁^Val by YfiC has little influence on the cell growth under standard conditions, the yfiC gene confers a growth advantage under conditions of osmotic and oxidative stress.     

Analysis of purified tRNA species by polyacrylamide gel electrophoresis

Six purified amino acid acceptor tRNA species were examined by polyacrylamide gel electrophoresis. Small differences in migration were observed under conditions that preserve the conformation of tRNA. When tRNA was heated in the presence of either 10 mM acetate or EDTA at 60° a change in migration was observed for tRNA^Glu. No difference in migration was seen between Val-tRNA^Val and tRNA^Val. When tRNA was denatured by heating in 4M urea and applied to a gel containing the same amount of urea, all tRNA species migrated approximately the same distance with the exception of tRNA^{Leu V}, which showed an appreciable slower migration. From the difference in migration of tRNA^{Leu V} as compared to tRNA^Val and 5 S RNA, the difference in chain length between tRNA^Val and tRNA^{Leu V} was estimated to be approximately 9 nucleotides.     

Novel Temperature-Sensitive Mutants of Escherichia coli That Are Unable To Grow in the Absence of Wild-Type tRNA6Leu

Escherichia coli has only a single copy of a gene for tRNA₆^Leu (Y. Komine et al., J. Mol. Biol. 212:579–598, 1990). The anticodon of this tRNA is CAA (the wobble position C is modified to O²-methylcytidine), and it recognizes the codon UUG. Since UUG is also recognized by tRNA₄^Leu, which has UAA (the wobble position U is modified to 5-carboxymethylaminomethyl-O²-methyluridine) as its anticodon, tRNA₆^Leu is not essential for protein synthesis. The BT63 strain has a mutation in the anticodon of tRNA₆^Leu with a change from CAA to CUA, which results in the amber suppressor activity of this strain (supP, Su⁺6). We isolated 18 temperature-sensitive (ts) mutants of the BT63 strain whose temperature sensitivity was complemented by introduction of the wild-type gene for tRNA₆^Leu. These tRNA₆^Leu-requiring mutants were classified into two groups. The 10 group I mutants had a mutation in the miaA gene, whose product is involved in a modification of tRNAs that stabilizes codon-anticodon interactions. Overexpression of the gene for tRNA₄^Leu restored the growth of group I mutants at 42°C. Replacement of the CUG codon with UUG reduced the efficiency of translation in group I mutants. These results suggest that unmodified tRNA₄^Leu poorly recognizes the UUG codon at 42°C and that the wild-type tRNA₆^Leu is required for translation in order to maintain cell viability. The mutations in the six group II mutants were complemented by introduction of the gidA gene, which may be involved in cell division. The reduced efficiency of translation caused by replacement of the CUG codon with UUG was also observed in group II mutants. The mechanism of requirement for tRNA₆^Leu remains to be investigated.In the universal genetic code, 61 sense codons correspond to 20 amino acids, and the various tRNA species mediate the flow of information from the genetic code to amino acid sequences. Since codon-anticodon interactions permit wobble pairing at the third position, 32 tRNAs, including tRNA^fMet, should theoretically be sufficient for a complete translation system. Although some organisms have fewer tRNAs (1), most have abundant tRNA species and multiple copies of major tRNAs. For example, Escherichia coli has 86 genes for tRNA (79 genes identified in reference 14, 6 new ones reported in reference 3, and one fMet tRNA at positions 2945406 to 2945482) that encode 46 different amino acid acceptor species. Although abundant genes for tRNAs are probably required for efficient translation, the significance of the apparently nonessential tRNAs has not been examined.E. coli has five isoaccepting species of tRNA^Leu. According to the wobble rule, tRNA₁^Leu recognizes only the CUG codon. The CUG codon is also recognized by tRNA₃^Leu (tRNA₂^Leu) and thus tRNA₁^Leu may not be essential for protein synthesis. Similarly, tRNA₆^Leu is supposed to recognize only the UUG codon, but tRNA₄^Leu can recognize both UUA and UUG codons. Thus, tRNA₆^Leu appears to be dispensable. The existence of an amber suppressor mutation of tRNA₆^Leu (supP, Su⁺6) supports this possibility. tRNA₆^Leu is encoded by a single-copy gene, leuX (supP), and Su⁺6 has a mutation in the anticodon, which suggests loss of the ability to recognize UUG (26). Why are so many species of tRNA^Leu required? Holmes et al. (12) examined the utilization of the isoaccepting species of tRNA^Leu in protein synthesis and showed that utilization differs depending on the growth medium; in minimal medium, isoacceptors tRNA₂^Leu (cited as tRNA₃^Leu; see Materials and Methods) and tRNA₄^Leu are the predominant species that are found bound to ribosomes, but an increased relative level of tRNA₁^Leu is found bound to ribosomes in rich medium. The existence of tRNA₆^Leu is puzzling. This isoaccepting tRNA accounts for approximately 10% of the tRNA^Leu in total-cell extracts. However, little if any tRNA₆^Leu is found on ribosomes in vivo, and it is also only weakly active in protein synthesis in vitro with mRNA from E. coli (12). It thus appears that tRNA₆^Leu is only minimally involved in protein synthesis in E. coli.To investigate the role of tRNA₆^Leu in E. coli, we attempted to isolate tRNA₆^Leu-requiring mutants from an Su⁺6 strain. These mutants required wild-type tRNA₆^Leu for survival at a nonpermissive temperature. We report here the isolation and the characterization of these mutants.     

Position 34 of tRNA is a discriminative element for m5C38 modification by human DNMT2

Dnmt2, a member of the DNA methyltransferase superfamily, catalyzes the formation of 5-methylcytosine at position 38 in the anticodon loop of tRNAs. Dnmt2 regulates many cellular biological processes, especially the production of tRNA-derived fragments and intergenerational transmission of paternal metabolic disorders to offspring. Moreover, Dnmt2 is closely related to human cancers. The tRNA substrates of mammalian Dnmt2s are mainly detected using bisulfite sequencing; however, we lack supporting biochemical data concerning their substrate specificity or recognition mechanism. Here, we deciphered the tRNA substrates of human DNMT2 (hDNMT2) as tRNA^Asp(GUC), tRNA^Gly(GCC) and tRNA^Val(AAC). Intriguingly, for tRNA^Asp(GUC) and tRNA^Gly(GCC), G34 is the discriminator element; whereas for tRNA^Val(AAC), the inosine modification at position 34 (I34), which is formed by the ADAT2/3 complex, is the prerequisite for hDNMT2 recognition. We showed that the C³²U³³(G/I)³⁴N³⁵ (C/U)³⁶A³⁷C³⁸ motif in the anticodon loop, U11:A24 in the D stem, and the correct size of the variable loop are required for Dnmt2 recognition of substrate tRNAs. Furthermore, mammalian Dnmt2s possess a conserved tRNA recognition mechanism.     

Purification and nucleoside composition of a Q* - containing aspartic acid tRNA from Drosophila.

One form of aspartic acid tRNA from $\text{Drosophila}$,$\text{melanogaster}$ (tRNA_2δ^Asp) is selectively bound to columns of Con A-Sepharose. Unlike the other Q-containing tRNAs of $\text{Drosophila}$, it therefore appears that tRNA^Asp contains the more highly modified nucleoside, Q¹ (mannose form) in its anticodon. This is further supported by the chromatographic insensitivity of tRNA_2δ^Asp to NaIO₄ treatment. Utilizing Con A-Sepharose chromatography, tRNA_2δ^Asp from $\text{Drosophila}$ was purified and its nucleoside composition determined by chemical tritium labelling. In addition to the major nucleosides, this tRNA contains rT, hU, m⁵C, ψ, and Q¹, but no other modified nucleosides. Its nucleoside composition is very similar to yeast tRNA^Asp.     

N2-guanine specific transfer RNA methyltransferase II from rat liver

An enzyme was purified from rat liver and leukemic rat spleen which methylates guanosine residues in tRNA to N²-methylguanosine. By sequence analysis of bulk E. coli tRNA methylated with crude extracts it was shown that the enzyme is responsible for about 50% of total m²G formed invitro. The extent of methylation of a number of homogenous tRNA species was measured using the purified enzyme from both sources. Among tested E. coli tRNAs only tRNA^Arg, tRNA^Phe, and tRNA^Val yielded significantly more m²G than the bulk tRNA. The K_m for tRNA^Arg in the methylation reaction with enzymes from either tissue was 7.8 × 10⁻⁷ M as compared to the value 1 × 10⁻⁵ M obtained for the bulk tRNA. In a pancreatic RNase digest of bulk tRNA as well as of pure tRNA^Arg, tRNA^Phe, and tRNA^Val, A-m²G-Cp was found to be the only sequence methylated. Thus, the mammalian methyltransferase specifically recognizes the guanylate residue at position 10 from the 5′-end contained in a sequence (s⁴)U-A-G-Cp. Furthermore, there is no change between the enzyme from normal liver and leukemic spleen in the affinity for tRNA, the methylating capacity, and tRNA site and sequence recognition specificity.     

Activation of several tRNAs of Escherichia coli by the phenoxyacetyl derivative of N-hydroxysuccinimide

Escherichia coli 15T^? treated with chloramphenicol produces tRNA^phe which is deficient in minor nucleosides. Undermodified tRNA^phe chromatographs as two new peaks from a benzoylated diethylaminoethyl-cellulose column. Chloramphenicol tRNA^phe was purified by phenoxyacetylation of phenylalanyl-tRNA and subsequent chromatography on benzoylated diethylaminoethyl-cellulose. Purified tRNA^phe had an altered Chromatographie profile as a result of the purification procedure. Phenoxyacetylation of an unpurified tRNA preparation, which was either charged with phenylalanine or kept discharged, resulted in a permanent alteration of tRNA^phe which was similar to the alteration of the purified tRNA^phe. The altered tRNAs eluted with higher salt or ethanol concentrations from benzoylated diethylaminoethyl-cellulose. The alteration was also shown for tRNA^phe of phenoxyacetylated tRNA from late log phase E. coli 15T?. tRNA^glu and tRNA^Leu were not changed, but both tRNA^Arg and tRNA^Ile were altered. tRNA₂^Val and tRNA^Met shifted in the elution profile; tRNA₁^Val and tRNA_f^Met were not affected.Comparison of the primary structures of the alterable and nonalterable tRNA's revealed that all alterable tRNA's have the undefined nucleoside X in the extra loop. Phenoxyacetylation of nucleoside X probably was the cause of the altered profiles.tRNA^phe from E. coli 15T^? treated with chloramphenicol was less reactive towards phenoxyacetylation than normal tRNA, possibly because of a different conformation of the modification-deficient molecule relative to the normal tRNA^phe. tRNA^phe from E. coli 15T^?, starved for cysteine and methionine and treated with chloram-phenicol, is more deficient in minor nucleosides and showed even less reactivity.Acceptor capacities of the altered tRNA species were not changed significantly; only the acceptor capacity for tRNA^Ile decreased approximately 25%. The recognition site for the aminoacyl-tRNA synthetases probably is not affected.     

Sequences of three transfer RNAs from mosquito mitochondria

The sequences of three transfer RNAs from mosquito cell mitochondria, tRNA_UCG^Arg, tRNA_GUC^Asp, and tRNA_GAU^Ile, determined using a combination of rapid ladder and fingerprinting procedures are reported. These were compared with hamster mitochondrial tRNA_UCG^Arg and tRNA_GUC^Asp determined similarly, and a bovine mitochondrial tRNA_GAU^Ile determined using a somewhat different approach. The primary sequences of the mosquito tRNAs were 35 to 65% homologous to the corresponding mammalian mitochondrial species, and bore little homology to “conventional” (bacterial or eucaryotic cytoplasmic) tRNA. The modification status of the mosquito mitochondrial tRNAs resembled that of mammalian mitochondrial tRNA. The results contribute to the generalization that metazoan mitochondrial tRNA constitutes a distinctive, albeit loosely structured, phylogenetic group.     

A minimalist glutamyl-tRNA synthetase dedicated to aminoacylation of the tRNAAsp QUC anticodon

Escherichia coli encodes YadB, a protein displaying 34% identity with the catalytic core of glutamyl-tRNA synthetase but lacking the anticodon-binding domain. We show that YadB is a tRNA modifying enzyme that evidently glutamylates the queuosine residue, a modified nucleoside at the wobble position of the tRNA^Asp QUC anticodon. This conclusion is supported by a variety of biochemical data and by the inability of the enzyme to glutamylate tRNA^Asp isolated from an E.coli tRNA-guanosine transglycosylase minus strain deprived of the capacity to exchange guanosine 34 with queuosine. Structural mimicry between the tRNA^Asp anticodon stem and the tRNA^Glu amino acid acceptor stem in prokaryotes encoding YadB proteins indicates that the function of these tRNA modifying enzymes, which we rename glutamyl-Q tRNA^Asp synthetases, is conserved among prokaryotes.     

Overproduction and purification ofEscherichia coli tRNALeu

Chemically synthesized genes encodingEscherichia coli tRNA ₁ ^Leu and tRNA ₂ ^Leu were ligated into the plasmid pTrc99B. then transformed intoEscherichia coli MT102, respectively. The positive transformants, named MT-Leu1 and MT-Leu2, were confirmed by DNA sequencing, and the conditions of cultivation for the two transformants were optimized. As a result, leucinc accepting activity of their total tRNA reached 810 and 560 pmol/A₂₆₀, respectively: the content of tRNA ₁ ^Leu was 50% of total tRNA from MT-Leu1, while that of tRNA ₂ ^Leu was 30% of total tRNA from MT-Leu2. Both tRNA^Leus from their rotal tRNs were fractionated to 1 600 pmol/A₂₆₀ after DEAE-Sepharose and BD-cellulose column chromatography. The accurate kinetic constants of aminoacylation of the two isoacceptors of tRNA^Leu catalyzed by leucyl-tRNA synthetase were determined.     

Chromosomal assignment of a large tRNA gene cluster (tRNALeu,tRNAGln, tRNALys,tRNAArg, tRNAGly) to 17p13.1

Summary A cluster of tRNA genes (tRNA _UAG ^Leu , tRNA _CUG ^Gln , tRNA _UUU ^Lys , tRNA _UCU ^Arg ) and an adjacent tRNA _GCC ^Gly have been assigned to human chromosome 17p12–p13.1 by in situ hybridization using a 4.2 kb human DNA fragment for tRNA^Leu, tRNA^Gln, tRNA^Lys, tRNA^Arg, and, for tRNA^Gly, 1.3 kb and 0.58 kb human DNA fragments containing these genes as probes. This localization was confirmed and refined to 17p13.100–p13.105 using a somatic cell hybrid mapping panel. Preliminary experiments with the biotiny lated tRNA Leu, Gln, Lys, Arg probe and metaphase spreads from other great apes suggest the presence of a hybridization site on the long arm of gorilla (Gorilla gorilla) chromosome 19 and the short arm of orangutan (Pongo pygmaeus) chromosome 19 providing further support for homology between HSA17, GGO19 and PPY19.     

In vivo identification of essential nucleotides in tRNALeu to its functions by using a constructed yeast tRNALeu knockout strain

The fidelity of protein biosynthesis requires the aminoacylation of tRNA with its cognate amino acid catalyzed by aminoacyl-tRNA synthetase with high levels of accuracy and efficiency. Crucial bases in tRNA^Leu to aminoacylation or editing functions of leucyl-tRNA synthetase have been extensively studied mainly by in vitro methods. In the present study, we constructed two Saccharomyces cerevisiae tRNA^Leu knockout strains carrying deletions of the genes for tRNA^Leu(GAG) and tRNA^Leu(UAG). Disrupting the single gene encoding tRNA^Leu(GAG) had no phenotypic consequence when compared to the wild-type strain. While disrupting the three genes for tRNA^Leu(UAG) had a lethal effect on the yeast strain, indicating that tRNA^Leu(UAG) decoding capacity could not be compensated by another tRNA^Leu isoacceptor. Using the triple tRNA knockout strain and a randomly mutated library of tRNA^Leu(UAG), a selection to identify critical tRNA^Leu elements was performed. In this way, mutations inducing in vivo decreases of tRNA levels or aminoacylation or editing ability by leucyl-tRNA synthetase were identified. Overall, the data showed that the triple tRNA knockout strain is a suitable tool for in vivo studies and identification of essential nucleotides of the tRNA.     

Overproduction and purification of Escherichia coli tRNALeu

Chemically synthesized genes encodingEscherichia coli tRNA ₁ ^Leu and tRNA ₂ ^Leu were ligated into the plasmid pTrc99B. then transformed intoEscherichia coli MT102, respectively. The positive transformants, named MT-Leu1 and MT-Leu2, were confirmed by DNA sequencing, and the conditions of cultivation for the two transformants were optimized. As a result, leucinc accepting activity of their total tRNA reached 810 and 560 pmol/A₂₆₀, respectively: the content of tRNA ₁ ^Leu was 50% of total tRNA from MT-Leu1, while that of tRNA ₂ ^Leu was 30% of total tRNA from MT-Leu2. Both tRNA^Leus from their rotal tRNs were fractionated to 1 600 pmol/A₂₆₀ after DEAE-Sepharose and BD-cellulose column chromatography. The accurate kinetic constants of aminoacylation of the two isoacceptors of tRNA^Leu catalyzed by leucyl-tRNA synthetase were determined. Project supported by the National Natural Science Foundation of China (Grant No. 39570164).