Large scale isolation and some properties of AGY-specific serine tRNA from bovine heart mitochondria

A method was developed for large scale isolation of AGY-specific serine tRNA (tRNASerAGY) from bovine heart mitochondria. By this method, 5 A260 units of tRNASerAGY were recovered from 6.3 kg of bovine hearts. The nucleotide sequence was identical to that reported previously. tRNASerAGY showed abnormal melting profiles, as was predicted from its unique primary sequence. Its secondary and/or tertiary structure was analyzed by nuclease digestion method. It was suggested that three extra base pairs could occur in the anticodon stem region, with one adenosine residue protruding. The T loop was quite sensitive to nuclease S1, suggesting that the T loop doesn't interact with other regions. This finding is consistent with the model proposed by Sundaralingam (1980). tRNASerAGY was aminoacylated in vitro with only mitochondrial enzyme but not with the enzymes from E. coli and yeast. The aminoacylation rate of tRNASerAGY with mitochondrial enzyme was much faster than that of cytosolic tRNASerUCN, perhaps reflecting differences due to the presence and absence of the D arm of the tRNAs.     

The aminoacylation of structurally variant phenylalanine tRNAs from mitochondria and various nonmitochondrial sources by bovine mitochondrial phenylalanyl-tRNA synthetase

Bovine mitochondrial (mt) phenylalanine tRNA (tRNAPhe) was purified on a large scale using a new hybridization assay method developed by the authors. Although its melting profile suggested a loose higher order structure, presumably influenced by the apparent loss of D loop-T loop interaction necessary for forming a rigid L-shaped tertiary structure, its aminoacylation capacity catalyzed by mt phenylalanyl-tRNA synthetase (PheRS) was nearly equal to that of Escherichia coli tRNAPhe. Misaminoacylation was not observed for the mt tRNAPhe-mt PheRS system. Comparing the aminoacylation efficiencies of several combinations of tRNAPheS and PheRSs from various sources, including bovine mitochondria, bovine and yeast cytosols, E. coli, Thermus thermophilus, and Sulfolobus acidocaldarius, it was clarified that mt PheRS was able to aminoacylate all the above mentioned tRNAPhe species, albeit with varying degrees of efficiency. This broad charging spectrum suggests that mt PheRS possesses a relatively simple recognition mechanism toward its substrate, tRNAPhe.     

Bovine mitochondrial tRNAPhe, tRNASer (AGY) and tRNASer (UCN): preparation using a new detection method and their properties in aminoacylation

Bovine mitochondrial tRNAPhe, tRNASer (AGY), and tRNASer (UCN) possessing unusual structures were purified using a new hybridization assay system and their properties in aminoacylation were examined. Bovine mitochondrial phenyl-alanyl- and seryl-tRNA synthetases could aminoacylate the same amino acid-specific tRNAs obtained not only from the mitochondria but also from other sources such as E. coli, Thermus thermophilus, bovine and yeast cytosols and archaebacteria, Sulfolobus acidocaldarius. On the contrary, none of both bacterial and cytosolic synthetases could aminoacylate the same amino acid specific tRNAs from the heterologous sources with some exceptions. We consider that the bovine mitochondrial aminoacyl-tRNA synthetases have considerably simple recognition mechanism toward the substrate tRNAs compared with the non-mitochondrial ones. This mechanism may be correlated with the occurrence of structural varieties of the mitochondrial tRNA species with unusual structures.     

Recognition of tRNAs by aminoacyl-tRNA synthetases: Escherichia coli tRNAMet and E. coli methionyl-tRNA synthetase

In previous work we identified several specific sites in Escherichia coli tRNAfMet that are essential for recognition of this tRNA by E. coli methionyl-tRNA synthetase (MetRS) (EC 6.1.1.10). Particularly strong evidence indicated a role for the nucleotide base at the wobble position of the anticodon in the discrimination process. We have now investigated the aminoacylation activity of a series of tRNAfMet derivatives containing single base changes in each position of the anticodon. In addition, derivatives containing permuted sequences and larger and smaller anticodon loops have been prepared. The variant tRNAs have been enzymatically synthesized in vitro by using T4 RNA ligase (EC 6.5.1.3). Base substitutions in the wobble position have been found to reduce aminoacylation rates by at least five orders of magnitude. Derivatives having base substitutions in the other two positions of the anticodon are aminoacylated 55-18,500 times slower than normal. Nucleotides that have specific functional groups in common with the normal anticodon bases are better tolerated at each of these positions than those that do not. A tRNAfMet variant having a six-membered loop containing only the CA sequence of the anticodon is aminoacylated still more slowly, and a derivative containing a five-membered loop is not measurably active. The normal loop size can be increased by one nucleotide with a relatively small effect on the rate of aminoacylation, which indicates that the spatial arrangement of the nucleotides is less critical than their chemical nature. We conclude from these data that recognition of tRNAfMet requires highly specific interactions of MetRS with functional groups on the nucleotide bases of the anticodon sequence. Several other aminoacyl-tRNA synthetases are known to require one or more anticodon bases for efficient aminoacylation of their tRNA substrates, and data from other laboratories suggest that anticodon sequences may be important for accurate discrimination between cognate and noncoagnate tRNAs by these enzymes.     

Aptamer redesigned tRNA is nonfunctional and degraded in cells

An RNA aptamer derived from tRNA(Gln) isolated in vitro and a rationally redesigned tRNA(Gln) were used to address the relationship between structure and function of tRNA(Gln) aminoacylation in Escherichia coli. Two mutant tRNA(Gln) sequences were studied: an aptamer that binds 26-fold tighter to glutaminyl-tRNA synthetase than wild-type tRNA(Gln) in vitro, redesigned in the variable loop, and a mutant with near-normal aminoacylation kinetics for glutamine, redesigned to contain a long variable arm. Both mutants were tested in a tRNA(Gln) knockout strain of E. coli, but neither supported knockout cell growth. It was later found that both mutant tRNAs were present in very low amounts in the cell. These results reveal the difference between in vitro and in vivo studies, demonstrating the complexities of in vivo systems that have not been replicated in vitro.     

The reliability of in vivo structure-function analysis of tRNA aminoacylation.

The G.U wobble base-pair in the acceptor helix of Escherichia coli tRNAAlais critical for aminoacylation by the alanine synthetase. Previous work by several groups probed the mechanism of enzyme recognition of G.U by a structure-function analysis of mutant tRNAs using either a cell assay (amber suppressor tRNA) or a test tube assay (phage T7 tRNA substrate and purified enzyme). However, the aminoacylation capacity of particular mutant tRNAs was about 10(4)-fold higher in the cell assay. This led us to scrutinize the cell assay to determine if any parameter exaggerates the extent of aminoacylation in mutants forming substantial amounts of alanyl-tRNAAla. In doing so, we have refined and developed experimental designs to analyze tRNA function. We examined the level of aminoacylation of amber suppressor tRNAAlawith respect to the method of isolating aminoacyl-tRNA, the rate of cell growth, the cellular levels of alanine synthetase and elongation factor TU (EF-Tu), the amount of tRNA and the characteristics of EF-Tu binding. Within the precision of our measurements, none of these parameters varied in a way that could significantly amplify cellular alanyl-tRNAAla. A key observation is that the extent of aminoacylation of tRNAAlawas independent of tRNAAlaconcentration over a 75-fold range. Therefore, the cellular assay of tRNAAlareflects the substrate quality of the molecule for formation of alanyl-tRNAAla. These experiments support the authenticity of the cellular assay and imply that a condition or factor present in the cell assay may be absent in the test tube assay.     

A single base pair affects binding and catalytic parameters in the molecular recognition of a transfer RNA

A single G3.U70 base pair in the acceptor helix is a major determinant of the identity of an alanine transfer RNA. Alteration of this base pair to A.U or G.C prevents aminoacylation with alanine. We show here that, at approximate physiological conditions (pH 7.5, 37 degrees C), high concentrations of the mutant A3.U70 species do not inhibit aminoacylation of a wild-type alanine tRNA. The observation suggests that, under these conditions, the G3 to A3 substitution increases Km for tRNA by more than 30-fold. Other experiments at pH 7.5 show that no aminoacylation of A3.U70, G3.C70, or U3.G70 mutant tRNAs occurs with substrate levels of enzyme. This suggests that kcat for these mutant tRNAs is sharply reduced as well and that the catalytic defect is not due to slow release of charged mutant tRNAs from the enzyme. Investigations were also done at pH 5.5, where association of tRNAs with synthetases is generally stronger and where binding can be conveniently measured apart from aminoacylation. Under these conditions, the binding of the A3.U70 and G3.C70 species is readily detected and is only 3-5-fold weaker than the binding of the wild-type tRNA. Although the A3.U70 species was demonstrated to compete with the wild-type tRNA for the same site on the enzyme, no aminoacylation could be detected. Thus, even when conditions are adjusted to obtain strong competitive binding, a sharp reduction in kcat prevents aminoacylation of a tRNA(Ala) species with a substitution at position 3.70.     

Aminoacylation of anticodon loop substituted yeast tyrosine transfer RNA

A procedure for replacing residues 33-35 in the anticodon loop of yeast tRNATyr with any desired oligonucleotide has been developed. The three residues were removed by partial ribonuclease A digestion. An oligonucleotide was inserted into the gap in four steps by using RNA ligase, polynucleotide kinase, and pseT 1 polynucleotide kinase. The rate of aminoacylation of anticodon loop substituted tRNATyr by yeast tyrosyl-tRNA synthetase was found to depend upon the sequence of the oligonucleotide inserted. This suggests that the nucleotides in the anticodon loop of yeast tRNATyr are required for optimal aminoacylation. In addition, tRNATyr modified to have a phenylalanine anticodon was shown to be misacylated by yeast phenylalanyl-tRNA synthetase at a rate at least 10 times faster than unmodified tRNATyr. Thus, the anticodon is used by phenylalanyl-tRNA synthetase to distinguish between tRNAs.     

Nucleotide correlations that suggest tertiary interactions in the TV-replacement loop-containing mitochondrial tRNAs of the nematodes, Caenorhabditis elegans and Ascaris suum.

In the predicted secondary structures of 20 of the 22 tRNAs encoded in mitochondrial DNA (mtDNA) molecules of the nematodes, Caenorhabditis elegans and Ascaris suum, the T psi C arm and variable loop are replaced with a loop of 6 to 12 nucleotides: the TV-replacement loop. From considerations of patterns of nucleotide correlations in the central regions of these tRNAs, it seems highly likely that tertiary interactions occur within five sets of binary and ternary combinations of nucleotides that correspond in location to nucleotides known to be involved in tertiary interactions in yeast tRNA(Phe) and other standard tRNAs. These observations are consistent with the nematode TV-replacement loop-containing mt-tRNAs being folded into a similar L-shaped functional form to that demonstrated for standard tRNAs, and for the bovine DHU (dihydrouridine) arm replacement-loop-containing mt-tRNA(Ser(AGY)). However, the apparent occurrence in nematode mt-tRNAs of tertiary bonds common to standard tRNAs contrasts with the situation in bovine mt-tRNA(Ser(AGY)) where the functional form is dependent on an almost unique set of tertiary interactions. Because three of the proposed conserved tertiary interactions in the nematode mt-tRNAs involve nucleotides that occur in the variable loop in standard tRNAs, it seems more likely that in nematode mt-tRNAs it is the T psi C arm rather than the variable loop that has undergone the greatest proportional decrease in nucleotide number.     

Primary structure of E. coli alanine transfer RNA: relation to the yeast phenylalanyl tRNA synthetase recognition site

Nucleotide sequence comparison of tRNAs aminoacylated by yeast phenylalanyl tRNA synthetase (PRS) have lead to the proposal that the specific nucleotides of the dihydrouridine (diHU) stem region and adenosine at the fourth position from the 3′ end are involved in the PRS recognition site. Kinetic analysis and enzymatic methylation have shown that the size of the diHU loop and the methylation of guanine at position 10 from the 5′ end both directly affect the PRS aminoacylation kinetics. $\text{E. coli}$ tRNA₁^A1a, which is aminoacylated by PRS, should therefore have 1- the specific nucleotides of the diHU stem region and, 2- adenosine at position 4 from the 3′ end. The PRS aminoacylation kinetics of this tRNA indicates that this molecule 3- has a diHU loop of 8 nucleotides and 4- has an unmethylated guanine at position 10 from the 5′ end. We report here the complete sequence of $\text{E. coli}$ tRNA₁^A1a and confirmation of each of these four predictions.     

Relationship of the CCA sequence of tRNA with the early evolutional aspect of aminoacyl-tRNA synthetases.

The CCA sequence is common to the 3'-ends of all tRNAs. We investigated the requirement of the CCA sequence in aminoacylation with the cognate aminoacyl-tRNA synthetases (aaRSs) and several interesting conclusions could be drawn. In tRNAs belonging to the class I aaRSs, decreased aminoacylation activities resulted from the substitution of A76 with a pyrimidine, whereas in tRNAs belonging to the class II aaRSs, decreased aminoacylation activities resulted from the substitution with guanine. The results suggest that aminoacylation of proto-tRNA might have started through the direct hydrophobic (or stacking) interaction between the large, hydrophobic amino acid residue (now utilizing a class I aaRS) of aminoacyl-AMP and the 3'-terminal adenine. The shorter distance between the adenine and the 2'-OH position than the 3'-OH position, and the bulkiness and hydrophobicity of amino acids may be important reasons why class I aaRSs select the 2'-OH position in aminoacylation. Molecular mechanics-based conformation modeling also indicated that the resulting positioning of the adenine and the amino acid residue of 2'-aminoacyl-adenosine for large amino acid is in the vicinity. In contrast, in the case of small amino acids (with class II aaRSs) which would not be able to use the hydrophobic interaction, a protein enzyme might have participated in the aminoacylation reaction from an early stage. The active-site folds of aaRSs belonging to each class reflect the history of evolution: typical nucleotide-binding fold (Rossman fold) in the case of class I aaRSs, and primitive fold which is found also among the family of nonribosomal peptide synthetases in the case of class II aaRSs.     

Conformational requirements of tobacco mosaic virus RNA for aminoacylation and adenylation.

The RNA conformational requirements for both aminoacylation and adenylation emerging from our studies performed using the valine- and the tyrosine-accepting plant viral RNAs are now strongly supported by the histidine-accepting tobacco mosaic virus RNA: an 'L'-shaped conformation is recognized by the aminoacyl-tRNA synthetase whereas only the aminoacyl RNA domain (equivalent in tRNAs to the continuous helix formed by the acceptor stem and the T stem and loop) interacts with the tRNA nucleotidyltransferase.     

Covariation of a specificity-determining structural motif in an aminoacyl-tRNA synthetase and a tRNA identity element

Transfer RNA (tRNA) identity determinants help preserve the specificity of aminoacylation in vivo, and prevent cross-species interactions. Here, we investigate covariation between the discriminator base (N73) element in histidine tRNAs and residues in the histidyl-tRNA synthetase (HisRS) motif 2 loop. A model of the Escherichia coli HisRS--tRNA(His) complex predicts an interaction between the prokaryotic conserved glutamine 118 of the motif 2 loop and cytosine 73. The substitution of Gln 118 in motif 2 with glutamate decreased discrimination between cytosine and uracil some 50-fold, but left overall rates of adenylation and aminoacylation unaffected. By contrast, substitutions at neighboring Glu 115 and Arg 121 affected both adenylation and aminoacylation, consistent with their predicted involvement in both half-reactions. Additional evidence for the involvement of the motif 2 loop was provided by functional analysis of a hybrid Saccharomyces cerevisiae-- E. coli HisRS possessing the 11 amino acid motif 2 loop of the yeast enzyme. Despite an overall decreased activity of nearly 1000-fold relative to the E. coli enzyme, the chimera nevertheless exhibited a modest preference for the yeast tRNA(His) over the E. coli tRNA, and preferred wild-type yeast tRNA(His) to a variant with C at the discriminator position. These experiments suggest that part of, but not all of, the specificity is provided by the motif 2 loop. The close interaction between enzyme loop and RNA sequence elements suggested by these experiments reflects a covariation between enzyme and tRNA that may have acted to preserve aminoacylation fidelity over evolutionary time.     

Starvation-induced cleavage of the tRNA anticodon loop in Tetrahymena thermophila

Amino acid deprivation triggers dramatic physiological responses in all organisms, altering both the synthesis and destruction of RNA and protein. Here we describe, using the ciliate Tetrahymena thermophila, a previously unidentified response to amino acid deprivation in which mature transfer RNA (tRNA) is cleaved in the anticodon loop. We observed that anticodon loop cleavage affects a small fraction of most or all tRNA sequences. Accumulation of cleaved tRNA is temporally coordinated with the morphological and metabolic changes of adaptation to starvation. The starvation-induced endonucleolytic cleavage activity targets tRNAs that have undergone maturation by 5' and 3' end processing and base modification. Curiously, the majority of cleaved tRNAs lack the 3' terminal CCA nucleotides required for aminoacylation. Starvation-induced tRNA cleavage is inhibited in the presence of essential amino acids, independent of the persistence of other starvation-induced responses. Our findings suggest that anticodon loop cleavage may reduce the accumulation of uncharged tRNAs as part of a specific response induced by amino acid starvation.     

Higher-order structure of bovine mitochondrial tRNA(SerUGA): chemical modification and computer modeling.

On the basis of enzymatic probing and phylogenetic comparison, we have previously proposed that mammalian mitochondrial tRNA(sSer) (anticodon UGA) possess a slightly altered cloverleaf structure in which only one nucleotide exists between the acceptor stem and D stem (usually two nucleotides) and the anticodon stem consists of six base pairs (usually five base pairs) [Yokogawa et al. (1991) Nucleic Acids Res. 19, 6101-6105]. To ascertain whether such tRNA(sSer) can be folded into a normal L-shaped tertiary structure, the higher-order structure of bovine mitochondrial tRNA(SerUGA) was examined by chemical probing using dimethylsulfate and diethylpyrocarbonate, and on the basis of the results a tertiary structure model was obtained by computer modeling. It was found that a one-base-pair elongation in the anticodon stem was compensated for by multiple-base deletions in the D and extra loop regions of the tRNA(SerUGA), which resulted in preservation of an L-shaped tertiary structure similar to that of conventional tRNAs. By summarizing the findings, the general structural requirements of mitochondrial tRNAs necessary for their functioning in the mitochondrial translation system are considered.