Mutant enzymes and tRNAs as probes of the glutaminyl-tRNA synthetase: tRNA(Gln) interaction.

This paper focuses on several aspects of the specificity of mutants of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) and tRNA(Gln). Temperature-sensitive mutants located in glnS, the gene for GlnRS, have been described previously. The mutations responsible for the temperature-sensitive phenotype were analyzed, and pseudorevertants of these mutants isolated and characterized. The nature of these mutations is discussed in terms of their location in the three-dimensional structure of the tRNA(Gln).GlnRS complex. In order to characterize the specificity of the aminoacylation reaction, mutant tRNA(Gln) species were synthesized with either a 2'-deoxy AMP or 3'-deoxy AMP as their 3'-terminal nucleotide. Subsequent assays for aminoacylation and ATP/PPi exchange activity established the esterification of glutamine to the 2'-hydroxyl of the terminal adenosine; there is no glutaminylation of the 3'-OH group. This correlates with the classification of GlnRS as a class I aminoacyl-tRNA synthetase. Mutations in tRNA(Gln) are discussed which affect the recognition of GlnRS and the current concept of glutamine identity in E coli is reviewed.     

Exceptional codon recognition by the glutamine tRNAs in Saccharomyces cerevisiae.

Recently, it was shown that wild-type glutamine tRNAs in yeast cause low-level nonsense suppression that can be enhanced by increasing glutamine tRNA gene copy number. In order to investigate glutamine tRNA behavior further, anticodon mutations that confer nonsense suppression were identified in yeast sup70 gene, which codes for glutamine tRNA(CAG). In this study we show that suppressors derived by mutation severely limit growth such that suppressor-bearing spores germinate but arrest cell division at approximately the 50 cell stage. Analysis of a sup70 deletion was used to establish that growth limitation results from loss of wild-type glutamine tRNA(CAG) function. By exploiting the growth inhibition of sup70 alleles, some exceptional codon recognition properties of glutamine tRNAs were revealed. Our results indicate that amber suppressor glutamine tRNA(UAG) can translate 5'-CAG-3' glutamine codons with low efficiency in the presence of an A/C mismatch at the first position of the codon, suggesting that reading may occur at a low level by a two-out-of-three reading mechanism. In addition, when glutamine tRNA(CAA) is over-expressed in vivo, it translates 5'-CAG-3' codons using a mechanism that resembles prokaryotic-like U/G wobble, which normally does not occur in yeast. Our studies also suggest that the yeast glutamine tRNA suppressors could potentially be exploited to express ciliated protozoan genes that normally contain internal 5'-UAG-3' and 5'-UAA-3' codons.     

Mischarging mutants of Su+2 glutamine tRNA in E. coli. II. Amino acid specificities of the mutant tRNAs

Among the mischarging mutants isolated from strains with Su+2 glutamine tRNA, two double-mutants, A37A29 and A37C38, have been suggested to insert tryptophan at the UAG amber mutation site as determined by the suppression patterns of a set of tester mutants of bacteria and phages (Yamao et al., 1988). In this paper, we screened temperature sensitive mutants of E. coli in which the mischarging suppression was abolished even at the permissive temperature. Four such mutants were obtained and they were identified as the mutants of a structural gene for tryptophanyl-tRNA synthetase (trpS). Authentic trpS mutations, such as trpS5 or trpS18, also restricted the mischarging suppression. These results strongly support the previous prediction that the mutant tRNAs of Su+2, A37A29 and A37C38, are capable of interacting with tryptophanyl-tRNA synthetase and being misaminoacylated with tryptophan in vivo. However, in an assay to determine the specificity of the mutant glutamin tRNAs, we detected predominantly glutamine, but not any other amino acid, being inserted at an amber codon in vivo to any significant degree. We conclude that the mutant tRNAs still accept mostly glutamine, but can accept tryptophan in an extent for mischarging suppression. Since the amber suppressors of Su+7 tryptophan tRNA and the mischarging mutants of Su+3 tyrosine tRNA are charged with glutamine, structural similarity among the tRNAs for glutamine, tryptophan and tyrosine is discussed.     

Suppressors of lysine codons may be misacylated lysine tRNAs

We describe a novel class of missense suppressors that read the codons for lysine at two positions (211 and 234) in the trpA polypeptide of Escherichia coli. The suppressor mutations are highly linked to lysT, a gene for lysine tRNA. The results suggest that the suppressors are misacylated lysine tRNAs that carry glycine or alanine. The mutant codons are apparently suppressed better at position 211 than at position 234, indicating the existence of codon context effects in missense suppression.     

Mischarging single and double mutants of Escherichia coli sup3 tyrosine transfer RNA

Mischarging mutants of Escherichia coli sup3 tyrosine transfer RNA have been isolated by selecting for suppression of bacterial amber mutations not suppressed by sup3. Five of the mutants have single base changes in the amino acid acceptor stem (A1, A2, U80, U81 and G82). Mutants A1 and A2 are weak thermosensitive suppressors from which thermostable derivatives have been isolated. Some of these derivatives affect the amount of tRNA synthesized but not the sequence (precursor or promoter mutations), and others are double mutants A1U81 and A2U80. The latter mutant does not mischarge. The efficiency of suppression of A1 and A2 can also be increased by recombination events that lead to duplication and triplication of the suppressor gene.The amino acid inserted by some of these mutants at the amber site has been determined. Mutant A1 inserts glutamine, while U81 and A1U81 insert both glutamine and tyrosine.Taken together the results show that the terminal part of the amino acid acceptor stem has an important role in the specificity of aminoacylation by the glutamine and tyrosine synthetase.     

Insertions in the anticodon loop of tRNA1Gln(sufG) and tRNA(Lys) promote quadruplet decoding of CAAA

Base insertion mutations in the anticodons of two different Escherichia coli tRNAs have been isolated that allow suppression of a series of +1 frameshift mutations. Insertion of a U between positions 34 and 35 of tRNAGln1 or addition of a G between positions 36 and 37 of tRNA(Lys) expand the anticodons of both tRNAs similarly to 3'-GUUU(-5') and allow decoding of complementary 5'-CAAA(-3') quadruplets. Analysis of the suppressed mRNA sequences suggests that suppression occurs by pairing of the expanded anticodons to all four bases of the complementary, quadruplet codon. The tRNA Gln mutants are identical to the sufG class of frameshift suppressors isolated both in Salmonella enterica serovar Typhimurium and E. coli by Kohno and Roth and previously thought to affect tRNA(Lys).     

First position wobble in codon-anticodon pairing: amber suppression by a yeast glutamine tRNA

A 2.4-kb fragment of DNA isolated from the Saccharomyces cerevisiae genome was found to suppress amber mutations when its carrier plasmid was present in high copy number. A 1.2-kb subclone of this fragment was sufficient to confer suppressor activity. Sequencing has established that this fragment carries a normal glutamine tRNA gene. Deletion of this tRNA gene from the subclone resulted in the loss of suppressor activity. The tRNAGln has the anticodon CUG that normally recognizes the glutamine codon CAG. We propose that suppression occurs via an inefficient readthrough of the UAG amber stop codons during translation. Such readthrough requires wobble in the first position of the codon.     

Dominant and recessive informational suppressors of a missense mutation in Coprinus

Summary Twenty-one suppressor gene mutations which suppress the met-5.1 missense mutation of Coprinus were separated into six groups (A-F) on the basis of dominance or recessiveness, linkage to the met-5 locus, comlementation in heterozygous cells and growth behaviour. The actual number of suppressor loci could not be determined because crosses between suppressed mutants were inviable. The allele specificity of group A, C, D and F suppressors was confirmed by appropriate crosses. Group B and E suppressors were not tested because of close linkage to the met-5 locus. No evidence for functional suppression of met-5 mutations was obtained thus it is likely that all the suppressors cause translational corelation of met-5.1. Suppressors in four groups (C-F) have properties expected of tRNA structural gene mutations: the group C mutation is dominant, the other mutations are recessive but do not complement in heterozygous cells. The relative efficiencies of the tRNA species involved was assessed by comparing the degree to which the different sup ⁺ mutations depressed the growth rate on methionine supplemented medium. The dominant mutation depressed growth to the greatest extent and is, therefore, the most efficient suppressor. The least efficient suppressors did not depress growth at all. When growth was compared on minimal medium it was found that the more efficient the suppressor the less well it restored growth. The mutations in groups A and B depressed growth more than the tRNA mutations but affect some other component in translation because they are recessive and complement normally. It is suggested that they may act to alter tRNA modifying enzymes.     

Intragenic Suppressors of Folding Defects in the P22 Tailspike Protein

Within the amino acid sequences of polypeptide chains little is known of the distribution of sites and sequences critical for directing chain folding and assembly. Temperature-sensitive folding (tsf) mutations identifying such sites have been previously isolated and characterized in gene 9 of phage P22 encoding the tailspike endorhamnosidase. We report here the isolation of a set of second-site conformational suppressors which alleviate the defect in such folding mutants. The suppressors were selected for their ability to correct the defects of missense tailspike polypeptide chains, generated by growth of gene 9 amber mutants on Salmonella host strains inserting either tyrosine, serine, glutamine or leucine at the nonsense codons. Second-site suppressors were recovered for 13 of 22 starting sites. The suppressors of defects at six sites mapped within gene 9. (Suppressors for seven other sites were extragenic and distant from gene 9.) The missense polypeptide chains generated from all six suppressible sites displayed ts phenotypes. Temperature-sensitive alleles were isolated at these amber sites by pseudoreversion. The intragenic suppressors restored growth at the restrictive temperature of these presumptive tsf alleles. Characterization of protein maturation in cells infected with mutant phages carrying the intragenic suppressors indicates that the suppression is acting at the level of polypeptide chain folding and assembly.     

Novel UGA-suppressors in Escherichia coli K-12

UGA-specific nonsense suppressors from Escherichia coli K-12 were isolated and characterized. One of them (Su+UGA-11) was identified as a mutant of the prfB gene for the peptide releasing factor RF2. It appears that in this strain, while peptide release at sites of UGA mutations is retarded, the UGA stop codon is read through even in the absence of a tRNA suppressor, exhibiting a novel type of passive nonsense suppression. Three suppressors (Su+UGA-12, -16 and -34) were capable of restoring the streptomycin sensitive phenotype in resistant bacteria (strAr). Because of their drug-related phenotype, these are possibly mutations in the components of the ribosomal machinery, particularly those concerned with peptide release at UGA nonsense codons. A tRNA suppressor was also obtained which was derived from the tRNA(Trp) gene. In this strain, a long region between rrnC (84.5 min) and rrnB (89.5 min) was duplicated and one of the duplicated genes of tRNA(Trp) was mutated to the suppressor. The mechanism of UGA-suppression is discussed in terms of translation termination at the nonsense codon in both active and passive fashions.     

The genes sup-7 X and sup-5 III of C. elegans suppress amber nonsense mutations via altered transfer RNA

The sup-5 III and sup-7 X suppressors in C. elegans have previously been shown to have many genetic properties in common with tRNA nonsense suppressors of microorganisms. We report here the results of two lines of investigation into the molecular basis of these suppressors. In one, which sought to determine the nature of suppressible alleles, we demonstrate through DNA sequencing studies that a suppressible allele, unc-54(e 1300) I, of the myosin heavy chain gene contains a C leads to T substitution, which changes a glutamine codon to amber terminator at residue 1903. In the other approach, which sought to define the nature of the suppressing activity, we show through in vitro translation studies that tRNA fractions from the suppressor strains, but not wild-type, promote the specific readthrough of amber terminators of three different messenger RNAs. We conclude that sup-5 and sup-7 result in readthrough of amber terminators in vivo through an altered tRNA.     

Nonsense and missense translational suppression in plant cells mediated by tRNALys

A nuclear tRNA^Lys gene from Arabidopsis thaliana was cloned and mutated so as to express tRNAs with altered anticodons which bind to a UAG nonsense (amber) codon and to the Arg (AGG), Asn (AAC,AAT), Gln (CAG) or Glu (GAG) codons. Concomitantly, a codon in the firefly luciferase gene for a functionally important Lys was altered to an amber codon, or to Arg, Asn, Gln, Glu, Thr and Trp codons, so as to construct reporter genes reliant upon incorporation of Lys. The altered tRNA^Lys and luciferase genes were introduced into Nicotiana benthamiana protoplasts and expression of the mutated tRNAs was verified by translational suppression of the mutant firefly luciferase genes. Expression of the amber suppressor tRNA _CUA ^Lys from non-replicative vectors promoted 10–40% suppression of the luciferase nonsense reporters while expression of the amber and missense tRNA^Lys suppressor genes from a geminivirus vector capable of replication promoted 30–80% suppression of the luciferase nonsense reporter and up to 10% suppression of the luciferase missense reporters with Arg, Asn, Gln and Glu codons.     

Neomycin is more efficient than streptomycin in suppressing frameshift mutations

The effects of streptomycin and neomycin on the phenotypic suppression of frameshift mutations in the lacZ gene of Escherichia coli and on the efficiency of suppression of amber mutations in T4 phage by the informational supE tRNA nonsense suppressor were compared. Neomycin stimulated much more efficiently than streptomycin the phenotypic suppression of frameshift mutations. Because neomycin favors mismatches of the central codon base whereas streptomycin favors mismatches of the first codon base, this result suggests that mismatching of the central codon base pair and shifting of the reading frame are two correlated phenomena. In contrast, both streptomycin and neomycin stimulated about equally the efficiency of the tRNA nonsense suppressor, an effect probably related to their interference with the proofreading control in tRNA selection.     

Single amino acid changes in AspRS reveal alternative routes for expanding its tRNA repertoire in vivo

Aminoacyl-tRNA synthetases (aaRSs) are enzymes that are highly specific for their tRNA substrates. Here, we describe the expansion of a class IIb aaRS-tRNA specificity by a genetic selection that involves the use of a modified tRNA displaying an amber anticodon and the argE(amber) and lacZ(amber) reporters. The study was performed on Escherichia coli aspartyl-tRNA synthetase (AspRS) and amber tRNA(Asp). Nine AspRS mutants able to charge the amber tRNA(Asp) and to suppress the reporter genes were selected from a randomly mutated library. All the mutants exhibited a new amber tRNA(Asp) specificity in addition to the initial native tRNA(Asp). Six mutations were found in the anticodon-binding site located in the N-terminal OB-fold. The strongest suppressor was a mutation of residue Glu-93 that contacts specifically the anticodon nucleotide 34 in the crystal structure. The other mutations in the OB-fold were found at close distance from the anticodon in the so-called loop L45 and strand S1. They concern residues that do not contact tRNA(Asp) in the native complex. In addition, this study shows that suppressors can carry mutations located far from the anticodon-binding site. One such mutation was found in the synthetase hinge-module where it increases the tRNA(Asp)-charging rate, and two other mutations were found in the prokaryotic-specific insertion domain and the catalytic core. These mutants seem to act by indirect effects on the tRNA acceptor stem binding and on the conformation of the active site of the enzyme. Altogether, these data suggest the existence of various ways for modifying the mechanism of tRNA discrimination.     

Construction of Escherichia coli amber suppressor tRNA genes. III. Determination of tRNA specificity

Using synthetic oligonucleotides, we have constructed a collection of Escherichia coli amber suppressor tRNA genes. In order to determine their specificities, these tRNAs were each used to suppress an amber (UAG) nonsense mutation in the E. coli dihydrofolate reductase gene fol. The mutant proteins were purified and subjected to N-terminal sequence analysis to determine which amino acid had been inserted by the suppressor tRNAs at the position of the amber codon. The suppressors can be classified into three groups on the basis of the protein sequence information. Class I suppressors, tRNA(CUAAla2), tRNA(CUAGly1), tRNA(CUAHisA), tRNA(CUALys) and tRNA(CUAProH), inserted the predicted amino acid. The class II suppressors, tRNA(CUAGluA), tRNA(CUAGly2) and tRNA(CUAIle1) were either partially or predominantly mischarged by the glutamine aminoacyl tRNA synthetase. The class III suppressors, tRNA(CUAArg), tRNA(CUAAspM), tRNA(CUAIle2), tRNA(CUAThr2), tRNA(CUAMet(m)) and tRNA(CUAVal) inserted predominantly lysine.     

Functional Analysis of Human tRNA Isodecoders

tRNA isodecoders share the same anticodon but have differences in their body sequence. An unexpected result from genome sequencing projects is the identification of a large number of tRNA isodecoder genes in mammalian genomes. In the reference human genome, more than 270 isodecoder genes are present among the approximately 450 tRNA genes distributed among 49 isoacceptor families. Whether sequence diversity among isodecoder tRNA genes reflects functional variability is an open question. To address this, we developed a method to quantify the efficiency of tRNA isodecoders in stop-codon suppression in human cell lines. First, a green fluorescent protein (GFP) gene that contains a single UAG stop codon at two distinct locations is introduced. GFP is only produced when a tRNA suppressor containing CUA anticodon is co-transfected with the GFP gene. The suppression efficiency is examined for 31 tRNA isodecoders (all contain CUA anticodon), 21 derived from four isoacceptor families of tRNA^Ser genes, 7 from five families of tRNA^Leu genes, and 3 from three families of tRNA^Ala genes. We found that isodecoder tRNAs display a large difference in their suppression efficiency. Among those with above background suppression activity, differences of up to 20-fold were observed. We were able to tune tRNA suppression efficiency by subtly adjusting the tRNA sequence and inter-convert poor suppressors into potent ones. We also demonstrate that isodecoder tRNAs with varying suppression efficiencies have similar stability and exhibit similar levels of aminoacylation in vivo. Our results indicate that naturally occurring tRNA isodecoders can have large functional variations and suggest that some tRNA isodecoders may perform a function distinct from translation.     

Suppressors of a UGG missense mutation in Escherichia coli

As part of our investigation of tRNA structure-function relationships, we isolated and preliminarily characterized translational suppressors of the tryptophan codon UGG in a trpA missense mutant of Escherichia coli. the parent strain also contained two other mutant alleles relevant to the suppressor search; these were supD, which codes for a serine-inserting amber suppressor tRNA, and gly V55, the gene for a GGA/G-reading mutationally altered glycine tRNA. On the basis of map location, reversed-phase (RPC-5) column chromatography of glycyl-tRNA, and codon response, several classes have been distinguished so far. The number of suppressors in each class, their codon responses, and their apparent genic identities, respectively, are as follows: class 1--4 suppressors, UGG, supD; class 2--12 suppressors, UGG, glyU; class 3--9 suppressors, UGA and UGG, glyT; class 4--2 suppressors, UGG, glyT; class 5--7 suppressors, UGG, gly V55. Besides these, one suppressor retains supD activity, but so far its map location has not been distinguished from that of supD. Another suppressor clearly does not map near supD or any of the glycine tRNA genes mentioned. These last two suppressors may represent novel missense suppressors such as misacylated tRNA's or mutationally altered aminoacyl-tRNA synthetases, tRNA modification enzymes, or ribosomes. Finally, three other suppressors were obtained from a strain containing glyT56, the gene for an AGA/G-reading form of glyT tRNA. All three occurred at the expense of glyT56 activity and exhibited the the transductional linkage to argH that is characteristic of glyT.     

tRNASer(CGA) differentially regulates expression of wild-type and codon-modified papillomavirus L1 genes

Exogenous transfer RNAs (tRNAs) favor translation of bovine papillomavirus 1 wild-type (wt) L1 mRNA in in vitro translation systems (Zhou et al. 1999, J. Virol., 73, 4972–4982). We, therefore, investigated whether papillomavirus (PV) wt L1 protein expression could be enhanced in eukaryotic cells following exogenous tRNA supplementation. Both Chinese hamster ovary (CHO) and Cos1 cells, transfected with PV1 wt L1 genes, effectively transcribed the genes but did not translate them. However, L1 protein translation was demonstrated following co-transfection with the L1 gene and a gene expressing tRNA^Ser(CGA). Cell lines, stably transfected with a bovine papillomavirus 1 (BPV1) wt L1 expression construct, produced L1 protein after the transfection of the tRNA^Ser(CGA) gene, but not following the transfection with basal vectors, suggesting that tRNA^Ser(CGA) gene enhanced wt L1 translation as a result of endogenous tRNA alterations and phosphorylation of translation initiation factors elF4E and elF2α in the tRNA^Ser(CGA) transfected L1 cell lines. The tRNA^Ser(CGA) gene expression significantly reduced translation of L1 proteins expressed from codon-modified (HB) PV L1 genes utilizing mammalian preferred codons, but had variable effects on translation of green fluorescent proteins (GFPs) expressed from six serine GFP variants. The changes of tRNA pools appear to match the codon composition of PV wt and HB L1 genes and serine GFP variants to regulate translation of their mRNAs. These findings demonstrate for the first time in eukaryotic cells that translation of the target genes can be differentially influenced by the provision of a single tRNA expression construct.