Specificity of codon recognition by Escherichia coli tRNALeu isoaccepting species determined by protein synthesis in vitro directed by phage RNA.

Codon-anticodon recognition and transfer RNA utilization for the leucine tRNA isoaccepting species of Escherichia coli have been studied by protein synthesis in vitro directed by sequenced bacteriophage MS2 RNA. We have added radioactive Leu-tRNA^Leu isoaccepting species as tracers, rather than use a tRNA-dependent system, since in the presence of an excess of non-radioactive leucine, there is no transfer of radioactive leucine from one isoaccepting species to another. MS2-specific peptides containing leucine residues encoded by known codons were isolated and identified, and the relative abilities of the Leu-tRNA^Leu isoaccepting species to transfer leucine into these peptides compared. Sequenced tRNA₁^Leu and sequenced tRNA₃^Leu are of roughly equal efficiency in their ability to recognize CUC and CUA codons, while tRNA₃^Leu is highly preferred for the CUU codon; tRNA₄^Leu and tRNA₅^Leu both recognize UUA and UUG codons, with tRNA₄^Leu slightly preferred for the UUA codon. We conclude that: (1) wobble is greater than permitted by the wobble hypothesis; (2) there is still some discrimination in the third code letter, and that the CUX₄ (CUC, CUA, CUU, CUG) portion of the leucine family of six codons is not read by a simple “two out of three” mechanism; (3) a Watson-Crick pair (C · G) between codon and anticodon does not appear to be preferred over an unorthodox pair (C · C) in the wobble position; (4) a standard wobble pair (U · G) between codon and anticodon is preferred over an unorthodox pair (U · C); and (5) the extensive wobble observed in the CUX₄ leucine codon series is not paralleled in the UUX₄ leucine (UUG, UUA) and phenylalanine (UUU, UUC) codon series, where mistranslation would be the consequence of such wobble.     

The CUG codon is decoded in vivo as serine and not leucine in Candida albicans.

Previous studies have shown that the yeast Candida albicans encodes a unique seryl-tRNA(CAG) that should decode the leucine codon CUG as serine. However, in vitro translation of several different CUG-containing mRNAs in the presence of this unusual seryl-tRNA(CAG) result in an apparent increase in the molecular weight of the encoded polypeptides as judged by SDS-PAGE even though the molecular weight of serine is lower than that of leucine. A possible explanation for this altered electrophoretic mobility is that the CUG codon is decoded as modified serine in vitro. To elucidate the nature of CUG decoding in vivo, a reporter system based on the C. albicans gene (RBP1) encoding rapamycin-binding protein (RBP), coupled to the promoter of the C. albicans TEF3 gene, was utilized. Sequencing and mass-spectrometry analysis of the recombinant RBP expressed in C. albicans demonstrated that the CUG codon was decoded exclusively as serine while the related CUU codon was translated as leucine. A database search revealed that 32 out of the 65 C. albicans gene sequences available have CUG codons in their open reading frames. The CUG-containing genes do not belong to any particular gene family. Thus the amino acid specified by the CUG codon has been reassigned within the mRNAs of C. albicans. We argue here that this unique genetic code change in cellular mRNAs cannot be explained by the 'Codon Reassignment Theory'.     

Codon reading and translational error. Reading of the glutamine and lysine codons during protein synthesis in vitro

The reading of glutamine and lysine codons during protein synthesis in vitro has been investigated using an MS2-RNA-programed system derived from Escherichia coli. Under conditions when either glutaminyl-tRNA1Gln (s2UUG) or glutaminyl-tRNA2Gln (CUG) was the only source of glutamine for protein synthesis both tRNAs were able to read the glutamine codons CAA and CAG as indicated by the incorporation of labeled glutamine into the pertinent coat protein tryptic peptides. On the other hand, when the two glutamine tRNAs competed for the codon CAA the reading efficiency of the anticodon s2UUG, which reads the codon according to the wobble rules, was almost 40 times higher than that of the competing anticodon CUG, which reads the codon by "two out of three," i.e. it cannot form a regular base pair with the third codon position. In reading the codon CAG the anticodon CUG was approximately eight times more efficient than the anticodon s2UUG. The lysyl-tRNA1Lys (CUU) could not alone sustain any detectable coat protein synthesis in the MS2 system indicating that there was no significant reading of the lysine codon AAA. This conclusion is supported by the outcome of experiments where lysyl-tRNA1Lys (CUU) and lysyl-tRNA2Lys (s2UUU) competed for the codon AAA. The reading efficiency of the anticodon CUU was less than 1% of that of the competing s2UUU which represents the limit of resolution of our experimental system. When the two lysine tRNAs competed for the codon AAG the anticodon CUU was about four times more efficient than s2UUU. These results are discussed in the context of the two out of three hypothesis, which attempts to relate the frequency of such reading to the hydrogen bonding properties of the codon nucleotides.     

Suppression of a double missense mutation by a mutant tRNA(Phe) in Escherichia coli.

We report here the isolation of a mutant tRNAPhe that suppresses a double missense auxotrophic mutation in trpA of Escherichia coli, trpA218. The doubly mutant protein product differs from wild-type TrpA by the replacements of Phe22 by Leu and Gly211 by Ser. A partial revertant TrpA phenotype can be obtained from trpA218 by changing either Leu22 back to Phe or Ser211 back to Gly. Translational suppressors were previously obtained that act at codon 211, replacing the Ser211 in the TrpA218 protein, presumably with Gly. In the present study, we selected for trpA218 suppressors caused by mutation of a cloned tRNAPhe gene, pheV. DNA sequence analysis of the suppressor isolated reveals a singular structural alteration, changing the anticodon from 5'-GAA-3' to 5'-GAG-3'. Sequencing of trpA218 confirmed the likely identity of Leu22 as CUC. The new missense suppressor, designated pheV(SuCUC), is lethal to the cell when highly expressed, as from a high copy number plasmid. This may be due to efficient replacement of Leu by Phe at CUC (and, probably, CUU) codons throughout the genome. We anticipate that pheV(SuCUC) will prove, like other missense suppressors, to be extremely useful in studies on the specificity and accuracy of decoding.     

The amino acid composition of proteins: a method of analysis.

Four quasiloglinear models are proposed for describing relationships between the amino acid composition of proteins and the structure of the genetic code. The models allow estimation of base frequencies in all three codon positions and can be used to investigate “interactions” between any two codon positions. The estimation procedure proposed by Ohta and Kimura (Genetics64 (1970), 387–395) is discussed and using two of the proposed quasiloglinear models an analysis of the amino acid composition of human cytochrome c is presented. The analysis suggests that of the six codons which code for leucine (CUU, CUC, CUA and CUG) do not occur in human cytochrome c.     

Measurement of translational accuracy in vivo: missense reporting using inactive enzyme mutants

The measurement and potential technological significance of in vivo missense errors are briefly reviewed. A recently developed approach is described in which reporter enzyme activity is generated by mistranslation of a gene coding for an inactive mutant form of the enzyme. Initial results obtained using the alpha subunit of E coli tryptophan synthetase and bacterial luciferase are discussed, as well as the prospects for further development of this method.     

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.     

Effects of mutations of the alpha His45 residue of Vibrio harveyi luciferase on the yield and reactivity of the flavin peroxide intermediate

This work was undertaken to investigate the functional consequences of mutations of the essential alpha His45 residue of Vibrio harveyi luciferase, especially with respect to the yield and reactivity of the flavin 4a-hydroperoxide intermediate II. A total of 14 luciferase variants, each with a different single-residue replacement for the alpha His45, were examined. These variants showed changes, mostly slight, in their light decay rates of the nonturnover luminescence reaction and in their Km values for decanal and reduced riboflavin 5'-phosphate (FMNH2). All alpha His45 mutants, however, showed markedly reduced bioluminescence activities, the magnitude of the reduction ranging from about 300-fold to 6 orders of magnitude. Remarkably, a good correlation was obtained for the wild-type luciferase, 12 alpha His45-mutated luciferases, and six additional variants with mutations of other alpha-subunit histidine residues between the degrees of luminescence activity reduction and the dark decay rates of intermediate II. Such a correlation further indicates that the activation of the O-O bond fission is an important function of the flavin 4a-hydroperoxide intermediate II. Both alpha H45G and alpha H45W were found to bind near-stoichiometric amounts of FMNH2. Moreover, each variant catalyzed the oxidation of bound FMNH2 by two mechanisms, with a minor pathway leading to the formation of a luminescence-active intermediate II and a major dark pathway not involving any detectable flavin 4a-hydroperoxide species. This latter pathway mimics that in the normal catalysis by flavooxidases, and its elicitation in luciferase was demonstrated for the first time by single-residue mutations.     

Ribosomal frameshifting in the yeast retrotransposon Ty: tRNAs induce slippage on a 7 nucleotide minimal site

Ribosomal frameshifting regulates expression of the TYB gene of yeast Ty retrotransposons. We previously demonstrated that a 14 nucleotide sequence conserved between two families of Ty elements was necessary and sufficient to support ribosomal frameshifting. This work demonstrates that only 7 of these 14 nucleotides are needed for normal levels of frameshifting. Any change to the sequence CUU-AGG-C drastically reduces frameshifting; this suggests that two specific tRNAs, tRNA(UAGLeu) and tRNA(CCUArg), are involved in the event. Our tRNA overproduction data suggest that a leucyl-tRNA, probably tRNA(UAGLeu), an unusual leucine isoacceptor that recognizes all six leucine codons, slips from CUU-Leu onto UUA-Leu (in the +1 reading frame) during a translational pause at the AGG-Arg codon induced by the low availability of tRNA(CCUArg), encoded by a single-copy essential gene. Frameshifting is also directional and reading frame specific. Interestingly, frameshifting is inhibited when the "slip" CUU codon is located three codons downstream, but not four or more codons downstream, of the translational initiation codon.     

Non-universal usage of the leucine CUG codon and the molecular phylogeny of the genus Candida

CUG, a universal leucine codon, was reported to be read as serine in 10 species of the genus Candida. We used an in vitro cell-free translation system to identify the amino acid assignment of codon CUG in 78 species and 7 varieties of galactose-lacking Candida species equipped with Q9 as the major ubiquinone. Of these, only 11 species used codon CUG as a leucine codon. The remaining species decoded CUG as serine. Their small subunit ribosomal DNA sequences were also determined and analyzed using both Neighbor-Joining and Maximum Likelihood methods. The species decoding CUG as serine and leucine formed distinct clusters on both molecular phylogenetic trees. Our result suggests that non-universal decoding is not a rare event, and that it is widely distributed in the genus Candida.     

Response

Summary  The posited universal cause of codon disappearance, extreme genomic % GC, is apparently not required for codon reassignment. Rigorously interpreted, this does not eliminate codon disappearance as a contributor to reassignment, but it implies that all reassignments are unlikely to be so caused. Even more significantly, the rationale for the axiom that reassigned codons must first disappear has been eliminated. That is, it has been asserted that a codon with two meanings would be lethal (Osawa and Jukes 1989). A complete inability to distinguish serine and leucine is of course lethal. However, a state of reduced ambiguity in which CUG means both serine and leucine not only stably exists in wild-type organisms in which leucine-to-serine reassignment has occurred, but such ambiguity may even have a favorable, rather than a lethal, phenotype. The potential list of possible ambiguous intermediates has been expanded by the discovery of the multiple amino acid specificity of Candida Ser- and Leu-tRNA^Ser (Suzuki et al. 1997). Other means of making codons ambiguous, such as ribosomal ambiguity or unusual concentrations or sequences of particular tRNAs, are easily envisioned. We look forward to further fossil ambiguous states and further elucidation of their phenotypes. From such data we may ultimately be able to deduce the forces that occasionally drive modern codons from one meaning to another.     

The sea pansy Renilla reniformis luciferase serves as a sensitive bioluminescent reporter for differential gene expression in Candida albicans.

The infectious yeast Candida albicans progresses through two developmental programs which involve differential gene expression, the bud-hypha transition and high-frequency phenotypic switching. To understand how differentially expressed genes are regulated in this organism, the promoters of phase-specific genes must be functionally characterized, and a bioluminescent reporter system would facilitate such characterization. However, C. albicans has adopted a nontraditional codon strategy that involves a tRNA with a CAG anticodon to decode the codon CUG as serine rather than leucine. Since the luciferase gene of the sea pansy Renilla reinformis contains no CUGs, we have used it to develop a highly sensitive bioluminescent reporter system for C. albicans. When fused to the galactose-inducible promoter of GAL1, luciferase activity is inducible; when fused to the constitutive EF1 alpha 2 promoter, luciferase activity is constitutive; and when fused to the promoter of the white-phase-specific gene WH11 or the opaque-phase-specific gene OP4, luciferase activity is phase specific. The Renilla luciferase system can, therefore, be used as a bioluminescent reporter to analyze the strength and developmental regulation of C. albicans promoters.     

Toxicity of a heterologous leucyl-tRNA (anticodon CAG) in the pathogen Candida albicans: in vivo evidence for non-standard decoding of CUG codons

Plasmids containing derivatives of the Saccharomyces cerevisiae leucyl-tRNA (tRNA3 ₃ ^Leu ) gene that vary in anticodon sequence were constructed and transformed into the pathogen Candida albicans and S. cerevisiae. C. albicans could readily be transformed with plasmids encoding leucyl-tRNA genes with the anticodons CAA and UAA (recognizing the codons UUG and UUA) and expression of the heterologous tRNA^Leu could be demonstrated by Northern RNA blotting. In contrast, no transformants were obtained if the anticodons were UAG (codons recognized CUN, UUR) and CAG (codon CUG), indicating that the insertion of leucine at CUG codons is toxic for C. albicans. All tRNA^Leu-encoding plasmids transformed S. cerevisiae with equally high efficiencies. These results provide in vivo evidence that non-standard decoding of CUG codons is essential for the viability of C. albicans.     

Initiation of translation by non-AUG codons in human T-cell lymphotropic virus type I mRNA encoding both Rex and Tax regulatory proteins

Human T-cell lymphotropic virus type I (HTLV-I) double-spliced mRNA exhibits two GUG and two CUG codons upstream to, and in frame with, the sequences encoding Rex and Tax regulatory proteins, respectively. To verify whether these GUG and CUG codons could be used as additional initiation codons of translation, two chimeric constructs were built for directing the synthesis of either Rex–CAT or Tax–CAT fusion proteins. In both cases, the CAT reporter sequence was inserted after the Tax AUG codon and in frame with either the Rex or Tax AUG codon. Under transient expression of these constructs, other proteins of higher molecular mass were synthesized in addition to the expected Rex–CAT and Tax–CAT proteins. The potential non-AUG initiation codons were exchanged for either an AUG codon or a non-initiation codon. This allowed us to demonstrate that the two GUG codons in frame with the Rex coding sequence, and only the second CUG in frame with the Tax coding sequence, were used as additional initiation codons. In HTLV-I infected cells, two Rex and one Tax additional proteins were detected that exhibited molecular mass compatible with the use of the two GUG and the second CUG as additional initiation codons of translation. Comparison of the HTLV-I proviral DNA sequence with that of other HTLV-related retroviruses revealed a striking conservation of the three non-AUG initiation codons, strongly suggesting their use for the synthesis of additional Rex and Tax proteins.     

The frequency of translational misreading errors in E. coli is largely determined by tRNA competition

Estimates of missense error rates (misreading) during protein synthesis vary from 10(-3) to 10(-4) per codon. The experiments reporting these rates have measured several distinct errors using several methods and reporter systems. Variation in reported rates may reflect real differences in rates among the errors tested or in sensitivity of the reporter systems. To develop a more accurate understanding of the range of error rates, we developed a system to quantify the frequency of every possible misreading error at a defined codon in Escherichia coli. This system uses an essential lysine in the active site of firefly luciferase. Mutations in Lys529 result in up to a 1600-fold reduction in activity, but the phenotype varies with amino acid. We hypothesized that residual activity of some of the mutant genes might result from misreading of the mutant codons by tRNA(Lys) (UUUU), the cognate tRNA for the lysine codons, AAA and AAG. Our data validate this hypothesis and reveal details about relative missense error rates of near-cognate codons. The error rates in E. coli do, in fact, vary widely. One source of variation is the effect of competition by cognate tRNAs for the mutant codons; higher error frequencies result from lower competition from low-abundance tRNAs. We also used the system to study the effect of ribosomal protein mutations known to affect error rates and the effect of error-inducing antibiotics, finding that they affect misreading on only a subset of near-cognate codons and that their effect may be less general than previously thought.