The accuracy of translation

Quality control of the elongation step of protein synthesis by tmRNP

Trans-translation is a quality-control process, activated upon premature termination of protein elongation, which recycles stalled ribosomes and degrades incomplete polypeptides. These functions are facilitated by transfer-messenger RNA (tmRNA, also called 10Sa RNA or SsrA RNA), a small stable RNA molecule encoded by the SsrA gene found in bacteria, chloroplasts and mitochondria. Most tmRNAs consist of a tRNA- and an mRNA-like domain connected by up to four pseudoknots. Comparative sequence analysis provided the first insight into tmRNA secondary and three-dimensional structure. Studies of the E. coli tmRNA in vitro and in vivo demonstrated that tmRNA functions as a ribonucleoprotein (RNP) complex with elongation factor Tu (EF-Tu), protein SmpB and ribosomal protein S1. The tRNA-like and mRNA-like activities of tmRNA mark prematurely terminated proteins for degradation by attaching to their C-termini peptide tags, which are recognized by numerous proteases. Studies aimed at understanding the details of the molecular mechanisms of trans-translation are ongoing.

Sense codon-dependent introduction of unnatural amino acids into multiple sites of a protein

Cell-free protein synthesis, driven by a crude S30 extract from Escherichia coli, has been applied to the preparation of proteins containing unnatural amino acids at specific positions. We have developed methods for inactivating tRNA(Asp) and tRNA(Phe) within a crude E. coli tRNA by an antisense treatment and for digesting most of the tRNA within the S30 extract without essential damage to the ribosomal activity. In the present study, we applied these methods to the substitution of Asp and Phe residues of the HIV-1 protease with unnatural amino acids. With 10 mM Mg(2+), the translation efficiency was higher than that with the other tested concentration, and the misreading efficiency was low. The protease mRNA was translated in the presence of an antisense DNA-treated tRNA mixture and 2-naphthylalanyl- and/or p-phenylazophenylalanyl-tRNA. The results suggest that a good portion of the translation products are substituted at all of the seven positions originally occupied by Asp or Phe.

Quality control mechanisms during translation

Translation uses the genetic information in messenger RNA (mRNA) to synthesize proteins. Transfer RNAs (tRNAs) are charged with an amino acid and brought to the ribosome, where they are paired with the corresponding trinucleotide codon in mRNA. The amino acid is attached to the nascent polypeptide and the ribosome moves on to the next codon. The cycle is then repeated to produce a full-length protein. Proofreading and editing processes are used throughout protein synthesis to ensure the faithful translation of genetic information. The maturation of tRNAs and mRNAs is monitored, as is the identity of amino acids attached to tRNAs. Accuracy is further enhanced during the selection of aminoacyl-tRNAs on the ribosome and their base pairing with mRNA. Recent studies have begun to reveal the molecular mechanisms underpinning quality control and go some way to explaining the phenomenal accuracy of translation first observed over three decades ago.

Progress toward the evolution of an organism with an expanded genetic code

Several significant steps have been completed toward a general method for the site-specific incorporation of unnatural amino acids into proteins in vivo. An "orthogonal" suppressor tRNA was derived from Saccharomyces cerevisiae tRNA2Gln. This yeast orthogonal tRNA is not a substrate in vitro or in vivo for any Escherichia coli aminoacyl-tRNA synthetase, including E. coli glutaminyl-tRNA synthetase (GlnRS), yet functions with the E. coli translational machinery. Importantly, S. cerevisiae GlnRS aminoacylates the yeast orthogonal tRNA in vitro and in E. coli, but does not charge E. coli tRNAGln. This yeast-derived suppressor tRNA together with yeast GlnRS thus represents a completely orthogonal tRNA/synthetase pair in E. coli suitable for the delivery of unnatural amino acids into proteins in vivo. A general method was developed to select for mutant aminoacyl-tRNA synthetases capable of charging any ribosomally accepted molecule onto an orthogonal suppressor tRNA. Finally, a rapid nonradioactive screen for unnatural amino acid uptake was developed and applied to a collection of 138 amino acids. The majority of glutamine and glutamic acid analogs under examination were found to be uptaken by E. coli. Implications of these results are discussed.

Engineering a tRNA and aminoacyl-tRNA synthetase for the site-specific incorporation of unnatural amino acids into proteins in vivo

In an effort to expand the scope of protein mutagenesis, we have completed the first steps toward a general method to allow the site-specific incorporation of unnatural amino acids into proteins in vivo. Our approach involves the generation of an "orthogonal" suppressor tRNA that is uniquely acylated in Escherichia coli by an engineered aminoacyl-tRNA synthetase with the desired unnatural amino acid. To this end, eight mutations were introduced into tRNA2Gln based on an analysis of the x-ray crystal structure of the glutaminyl-tRNA aminoacyl synthetase (GlnRS)-tRNA2Gln complex and on previous biochemical data. The resulting tRNA satisfies the minimal requirements for the delivery of an unnatural amino acid: it is not acylated by any endogenous E. coli aminoacyl-tRNA synthetase including GlnRS, and it functions efficiently in protein translation. Repeated rounds of DNA shuffling and oligonucleotide-directed mutagenesis followed by genetic selection resulted in mutant GlnRS enzymes that efficiently acylate the engineered tRNA with glutamine in vitro. The mutant GlnRS and engineered tRNA also constitute a functional synthetase-tRNA pair in vivo. The nature of the GlnRS mutations, which occur both at the protein-tRNA interface and at sites further away, is discussed.

Codon-reading specificity of an unmodified form of Escherichia coli tRNA1Ser in cell-free protein synthesis

Unmodified tRNA molecules are useful for many purposes in cell-free protein biosynthesis, but there is little information about how the lack of tRNA post-transcriptional modifications affects the coding specificity for synonymous codons. In the present study, we prepared an unmodified form of Escherichia coli tRNA1Ser, which originally has the cmo5UGA anticodon (cmo5U = uridine 5-oxyacetic acid) and recognizes the UCU, UCA and UCG codons. The codon specificity of the unmodified tRNA was tested in a cell-free protein synthesis directed by designed mRNAs under competition conditions with the parent tRNA1Ser. It was found that the unmodified tRNA with the UGA anti-codon recognizes the UCA codon nearly as efficiently as the modified tRNA. The unmodified tRNA recognized the UCU codon with low, but detectable efficiency, whereas no recognition of the UCC and UCG codons was detected. Therefore, the absence of modifications makes this tRNA more specific to the UCA codon by remarkably reducing the efficiencies of wobble reading of other synonymous codons, without a significant decrease in the UCA reading efficiency.

Interactions between tRNA identity nucleotides and their recognition sites in glutaminyl-tRNA synthetase determine the cognate amino acid affinity of the enzyme

Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs both ensure accurate RNA recognition and prevent the binding of noncognate substrates. Here we show for Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18) that the accuracy of tRNA recognition also determines the efficiency of cognate amino acid recognition. Steady-state kinetics revealed that interactions between tRNA identity nucleotides and their recognition sites in the enzyme modulate the amino acid affinity of GlnRS. Perturbation of any of the protein-RNA interactions through mutation of either component led to considerable changes in glutamine affinity with the most marked effects seen at the discriminator base, the 10:25 base pair, and the anticodon. Reexamination of the identity set of tRNA(Gln) in the light of these results indicates that its constituents can be differentiated based upon biochemical function and their contribution to the apparent Gibbs' free energy of tRNA binding. Interactions with the acceptor stem act as strong determinants of tRNA specificity, with the discriminator base positioning the 3' end. The 10:25 base pair and U35 are apparently the major binding sites to GlnRS, with G36 contributing both to binding and recognition. Furthermore, we show that E. coli tryptophanyl-tRNA synthetase also displays tRNA-dependent changes in tryptophan affinity when charging a noncognate tRNA. The ability of tRNA to optimize amino acid recognition reveals a novel mechanism for maintaining translational fidelity and also provides a strong basis for the coevolution of tRNAs and their cognate synthetases.

Unusual codon bias occurring within insertion sequences in Escherichia coli

The large open reading frames of insertion sequences from Escherichia coli were examined for their spatial pattern of codon usage bias and distribution of rarely used codons. There is a bias in codon usage that is generally lower toward the terminal ends of the coding regions, which is reflected in the occurrence of an excess of nonpreferred codons in the 3' portions of the coding regions as compared with the 5' portions. In contrast, typical chromosomal genes have a lower codon usage bias toward the 5' ends of the coding regions. These results imply that the selective forces reflected in codon usage bias may differ according to position within the coding sequence. In addition, these constraints apparently differ in important ways between genes contained in insertion sequences and those in the chromosome.

Correlation between poly(U) misreading and poly(dT) translation efficiency in E coli cell-free systems

A positive correlation between poly(U) misreading and efficiency of poly(dT) translation has been revealed in cell-free systems from wild-type E coli and streptomycin--resistant mutants with altered ribosomal protein S12. Different factors promoting misreading of poly(U) such as aminoglycoside antibiotics and Mg2+ ions also stimulate poly(dT) translation. The effect of the antibiotics on poly(U) translation efficiency and misreading as well as on poly(dT) decoding is characterised by the same order: neomycin greater than kanamycin greater than streptomycin. S12 mutants ribosomes are less erroneous in poly(U) translation and less efficient in poly(dT) decoding. The data obtained are in good agreement with the hypothesis of stereospecific stabilization of codon-anticodon complexes by the ribosome decoding centre.

Transfer RNA structure and coding specificity. II. A D-arm tertiary interaction that restricts coding range

We investigated the structural basis of the kinetic effect on coding specificity by the D-arm mutant (G24 to A) of Escherichia coli tRNATrp. A set of tRNA genes with structural alterations in the D-arm was constructed by site-directed mutagenesis in vitro, and we determined the in vivo translational activities of these tRNAs. Our results suggest that a hydrogen-bond donor in the major groove of the D-helix at position 24 is required for the expansion of tRNA wobble coding specificity. From inspection of tRNA crystal structure, we identified a potential new tertiary pairing of base 24 with the base at position 9 (this base links the acceptor and D-stems). We constructed tRNAs with mutations at position 9 and showed that the phenotypes of position 11-24 D-arm mutants are indeed dependent on the identity of base 9. Our analysis of the effects of these mutations on the interactions of tRNA with the ribosome and with aminoacyl-tRNA synthetase suggests that the conformation or conformational dynamics of the middle of the tRNA molecule alters the kinetics of the interaction with the ribosomal coding site. The 9-23 and putative 9-24 tertiaries, and perhaps other normal tertiary interactions in this region, modulate these kinetics to increase or decrease coding specificity.

Identification of minor tightly bound H1 histone subfractions which fail to cleave their initiator methionine

Groups of CBA mice were administered [35S] methionine (1 mCi/mouse). Non-histone proteins, H1 and H1(0) histones and nucleosomal core histones were isolated from different issues by selective extractions. The measurements of radioactivity of individual bands and autoradiography of dry gels were used to identify methionine-containing and methionine-free histone variants. H1A and H1B histone variants extracted with 5% perchloric acid were methionine-free. However, minor sub-fractions of these histones which are more tightly bound to DNA (and which can be extracted only with 0.25 N HCl) contained [35S] methionine and did show a higher specific activity than methionine-containing nucleosomal hitones. Cyanogen Bromide reaction which destroys non-histone proteins and methionine-containing nucleosomal histones removes radioactivity but does not alter the position of methionine-containing H1 minor bands. This indicates that the radioactive methionine occupies only the N-terminus of the H1 molecules. It is suggested that this methionine is an uncleaved initiator methionine. The presence of these methionine-containing minor H1 subfractions varies in different tissues.

Decreased accuracy of protein synthesis in extracts from aging human diploid fibroblasts

The accuracy of protein synthesis has been measured in extracts from human diploid fibroblasts of different ages. Extracts were supplied with purified mRNA for the coat protein of the cowpea variant of tobacco mosaic virus (CcTMV), which lacks codons for cysteine and methionine. The presence of 35S-cysteine in CcTMV coat protein synthesized during translation reactions therefore represents translational error. Translation reactions were performed with extracts from young fibroblasts (less than 50% of life span completed) and old fibroblasts (more than 90% of life span completed), and the translation products were purified by immunoprecipitation and analyzed by polyacrylamide gel electrophoresis. The error frequency increased from 4.2 x 10(-5) cysteines/amino acid in young cell extracts to 2.9 x 10(-4) cysteines/amino acid in old cell extracts. Cysteine incorporation was not due to nonspecific binding, and could be increased approximately sixfold by the addition of the misreading antibiotic, paromomycin. It is concluded that translational accuracy is not stable during aging in vitro, and it is proposed that this decrease in the fidelity of information transfer could be responsible for the variety of changes observed in aging cultured human cells.

High fidelity of guanine translation in a plasmid-directed in vitro system

The extent of misreading of individual bases in the first or second codon position has been measured in vitro in a simplified plasmid-directed coupled system in which natural messenger translation is restricted to the formation of the N-terminal di- or tripeptide. Experiments were performed under conditions of competition between cognate and noncognate tRNAs in the presence of streptomycin to maximize the frequency of reading errors. A striking lack of susceptibility to mistranslation of guanine, as compared to the other 3 bases, was observed.

Negative correlation between the abundance of Escherichia coli aminoacyl-tRNA families and their affinities for elongation factor Tu-GTP

The number of aminoacyl-tRNA molecules in Escherichia coli cells varies by about one order of magnitude from 730 (glutaminyl-tRNA) to 7900 (valyl-tRNA). Relative affinities of E. coli aminoacyl-tRNA for elongation factor Tu-GTP vary also by about one order of magnitude from 2.08 (glutaminyl-tRNA) to 0.15 (valyl-tRNA). The relationship between the abundance of all 20 aminoacyl-tRNA families in 5 E. coli strains and their affinities for elongation factor Tu-GTP was examined by statistical methods. Negative correlation between the two parameters was found. The correlation coefficient was -0.62 to -0.52 with significance level 0.01. Regression analysis give the following formula for the relation between relative abundance of aminoacyl-tRNA families (x) and their relative affinities for elongation factor Tu-GTP (y): y = 1.25 - 0.25x. The analyses indicate that those aminoacyl-tRNA families that are present in cells in low copy number exhibit higher affinity than the more abundant aminoacyl-tRNA families for elongation factor Tu-GTP. The bacterial protein biosynthetic apparatus evolved in such a way as to compensate for a low copy number of some aminoacyl-tRNAs by tight binding of the aminoacyl-tRNA to elongation factor Tu-GTP. This may assure adequate supply of low copy number aminoacyl-tRNAs under conditions of limitation in elongation factor Tu-GTP, e.g. during stringent response, and is consistent with the idea of elongation factor Tu-GTP modulating translational efficiencies of aminoacyl-tRNAs.

Inaccurate protein synthesis in a mutant of Salmonella typhimurium defective in transfer RNA pseudouridylation

Protein synthesis was studied comparatively in a wild-type strain of Salmonella typhimurium and in hisT mutant cells defective in the pseudouridylation of transfer RNA. From a quantitative point of view, no significant differences between the two types of strain was observed when measuring the rate of protein synthesis during either exponential growth or starvation for histidine. In contrast, the qualitative analysis of proteins by two-dimensional gel electrophoresis showed that histidine-starved hisT cells mistranslate the genetic program at a higher frequency than exponentially growing hisT cells or either starved or unstarved hisT+ cells.

Accuracy of natural messenger translation: analysis of codon-anticodon recognition in a simplified cell-free system

A simplified plasmid-directed coupled system [Robakis, N., Cenatiempo, Y., Meza-Basso, L., Brot, N., & Weissbach, H. (1983) Methods Enzymol. 101, 690-706] was used to study the accuracy of natural messenger translation in vitro. In this system, protein synthesis is limited to the formation of the N-terminal di- or tripeptide of the gene product. Such a control is obtained by restricting the supply of aminoacyl-tRNAs in the assay medium to those corresponding specifically to the first two or three triplets in the mRNA coding sequence. We analyzed comparatively the interaction of 6 different codons with their cognate tRNAs and 18 noncognate tRNAs able to recognize triplets differing from the legitimate sequences by one base only. Special attention was paid to the single base errors occurring at the first and second codon positions during ribosomal selection of aminoacyl-tRNA molecules. The noncognate tRNAs were assayed either in the absence of the legitimate tRNAs or under competition conditions. They were chosen so that all the possibilities for misreading any particular base as each of the other three bases could be studied. First, it was mainly observed that translation mistakes can be equally detected in the first and second codon positions; there is no compelling evidence for a most or least accurate site. Second, pyrimidines seem to be read more accurately than purines. In particular, U cannot be read as either C or G, and C can hardly be mistaken for any other base.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of post-transcriptional base modifications on the site-specific function of transfer RNA in eukaryote translation

The site-specific function in translation of several naturally occurring mammalian transfer RNAs has been studied in a series of investigations with some similarities to studies in other laboratories of tRNAs in suppression. Equal amounts of aminoacyl-tRNA isoacceptors with contrasting isotopes were added in pairs to reticulocyte lysates and allowed to incorporate their amino acids into rabbit globin. Rates of incorporation from unlimiting amounts of each isoacceptor into the corresponding amino-acid-containing sites were determined. The tRNAs of each isoacceptor pair differed as to post-transcriptional base modifications. The natural occurrence of these isoacceptors can be correlated with rates of cellular division, with more rapidly dividing and neoplastic cells containing hypomodified tRNA. The overall incorporation of lysine into globin from a fully modified tRNALys that decodes AAG is faster by 25 to 30% than from the corresponding hypomodified tRNALys. There is considerable scatter in values for incorporation ratios at different lysine-containing sites, with the hypomodified isoacceptor even being preferred at one site. The AAG decoding isoacceptors are capable of translating AAA although much more slowly than AAG. In translating AAA, in contrast to translating AAG, the hypomodified tRNALys isoacceptor is preferred. A Y base-deficient hypomodified tRNAPhe isoacceptor found only in some kinds of rapidly dividing tumor cells donates its phenylalanine preferentially to globin in competition with the fully modified Y-containing tRNAPhe of liver by 15 to 17%. There is a considerable range of incorporation ratios at the different phenylalanine-containing sites of the globin subunits. No correlation can be made between the isoacceptor preferred and the phenylalanine codon being translated. The incorporation of histidine from a fully modified tRNAHis-containing Q base in its anticodon, compared with that from the hypomodified counterpart isoacceptor that lacks Q base and that occurs in rapidly dividing cells, showed no difference in their ability to incorporate overall or into individual histidine-containing sites. There is little evidence that adjacent bases or codons in messenger RNA affect the tRNAs preferred in the translation of most sites. A striking pattern of tRNA preference was observed in three cases in which there are tandem codons, with the same codon appearing twice in succession.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of polyamines on translation fidelity in vivo

Polyamines, when added to cell-free protein-synthesizing systems, have been shown either to reduce mistranslation or to increase it depending upon the composition of the reaction mixture. To study this question under conditions as natural as possible we investigated the effects of polyamines on the fidelity of protein synthesis in intact Escherichia coli bacterial cells, using strains which were auxotrophic for polyamine synthesis. Error was measured in two ways: the incorporation of [3H]histidine into coat protein of bacteriophage MS2, the gene of which does not code for histidine, and the synthesis of a basic variant of MS2 coat protein in which a lysine erroneously replaces an asparagine, causing a change in isoelectric point. We found that when cell cultures were supplemented with polyamines there was no effect on the first type of error and the second type decreased twofold. The measured errors occurred at the level of translation because their frequency increased in the presence of streptomycin and decreased in cells bearing a streptomycin-resistance mutation known to lower the occurrence of translational misreading. The average erroneous incorporation per mol coat protein in the presence of polyamines was 1.43 +/- 0.59 mmol histidine and 25-34 mmol lysine/asparagine substitution. The reason for the different effect of polyamines on the two types of error is not known but could be related to the difference between their corresponding frequencies or to codon-specific effects.

Phenylalanyl-tRNA synthetases as an example for comparative and evolutionary aspects of aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases are indispensable components of protein synthesis in all three lines of evolutionary descent, eubacteria, archaebacteria and eukaryotes. Furthermore they are also present in the translational apparatus of the semi-autonomous organelles, mitochondria and chloroplasts, of the eukaryotic cell. Therefore aminoacyl-tRNA synthetases are appropriate objects for comparative molecular biology in order to obtain a comprehensive picture of the evolution of the translational process. The analysis of the phenylalanyl-tRNA synthetase in a large variety of organisms and organelles in this respect is the most advanced. In addition to comparison of quaternary structure, analysis includes functional aspects of accuracy mechanisms (proofreading) and comparison of structural features by means of substrate analogs. Evolutionary relationships are furthermore elucidated using the immunological approach and heterologous aminoacylation.

The accuracy of protein synthesis in reticulocyte and HeLa cell lysates

The accuracy of translation in protein synthesis is measured as the rate of misincorporation of a particular amino acid, different from that specified by an mRNA codon, into protein. The cowpea variant of tobacco mosaic virus, CcTMV, contains no cysteine or methionine in its coat protein. Translation in vitro of purified CcTMV coat protein mRNA by rabbit reticulocyte and HeLa cell lysates has been performed. The coat protein product was purified by immunoprecipitation with specific antisera, and separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The error rate was measured by comparing the incorporation of [35S]cysteine with incorporation of [3H]leucine, and the total CcTMV coat protein synthesized was calculated from its known leucine content. An error rate of (1-2) X 10(-3) cysteines/CcTMV coat protein was obtained with reticulocyte lysates. If errors were cysteine incorporation in place of arginine, this number is converted to 3 X 10(-4) cysteine/codon. If cysteine was incorporated anywhere in the polypeptide, the rate is 9 X 10(-6) cysteines/amino acid. The error frequencies with HeLa cell lysates were 6-fold higher. Paromomycin, a eukaryotic misreading antibiotic, increased error rates 10-fold in both lysates. These data compare well with in vivo measurements and suggest that some transformed cells may survive with higher mistranslation rates.

Two modes of amber codon read-through in vitro

Read-through translation of bacteriophage R17 amB2 coat cistron carrying an amber mutation at the seventh codon was studied in vitro using the crude cell extract (S30) derived from an Escherichia coli nonsuppressor strain. Despite the presence of termination factors as well as ribosome-releasing factor (RRF) which prevent the read-through translation [M. Ryoji, J. W. Karpen, and A. Kaji (1981) J. Biol. Chem. 256, 5798-5801], synthesis of coat-like protein still persists at a low level in this system. Characterization of this protein by peptide fingerprinting and amino acid sequencing was performed to reexamine the generally accepted notion that it is produced by amino acid misinsertion to the amber mutation codon. The results indicated, however, that the major population of this coat-like protein is produced as a result of reinitiation of translation from the eighth codon. Read-through by amino acid misinsertion in this system becomes predominant only when the Mg2+ concentration is higher than 16 mM.

An estimate on the effect of point mutation and natural selection on the rate of amino acid replacement in proteins

We outline a method for estimating quantitatively the influence of point mutations and selection on the frequencies of codons and amino acids. We show how the mutation rate, i.e., the rate of amino acid replacement due to point mutation, can be affected by the codon usage as well as by the rates of the involved base exchanges. A comparison of the mutation rates calculated from reliable values of codon usage and base exchange probabilities with those that would be expected on the basis of chance reveals a notable suppression of replacements leading to tryptophan, glutamate, lysine, and methionine, and particularly of those leading to the termination codons. If selection constraints are neglected and only mutations are taken into account, the best agreement between expected and observed frequencies of both codons and amino acids is obtained for alpha = 1.13-1.15, where (Formula: see text). The "selection values" of codons and amino acids derived by our method show a pattern that partially deviates from others in the literature. For example, the selection pressure on methionine and cysteine turns out to be much more pronounced than expected if only the discrepancies between their observed and expected occurrences in proteins are considered. To estimate to what extent randomly occurring amino acid replacements are accepted by selection, we constructed an "acceptability matrix" from the well-established matrix of accepted point mutations. On the basis of this matrix "acceptability values" of the amino acids can be defined that correlate with their selection values. We also examine the significance of mutations and selection of amino acids with respect to their physicochemical properties and functions in proteins. The conservatism of amino acid replacements with respect to certain properties such as polarity can be brought about by the mutational process alone, whereas the conservatism with respect to other relevant properties--among them all measures of bulkiness--obviously is the result of additional selectional constraints on the evolution of protein structures.

The secondary structure of mRNAs from Escherichia coli: its possible role in increasing the accuracy of translation

A secondary structure model was proposed for mRNAs during translation (in a polysome) where the secondary structure is described by a set of small unbranched hairpins. Computer simulation experiments reveal that the number of hairpins is much greater (P less than 10(-6) in highly expressed mRNAs from E. coli as compared with the random sequences coding for the same amino acid sequence, i.e. certain synonymous codons are used in definite mRNA positions to increase the number of hairpins. No constraints on the amino acid sequence, which would affect the secondary structure of mRNAs, were found. The codons UGU, UGC (Cys), GCC (Ala), ACA, ACG (Thr), CCU, CCC (Pro), etc. translated by minor tRNAs were found to occur significantly more frequently in the position 5' to the hairpins than the other codons translated by major tRNAs (P less than 5.10(-6). This correlation leads to the hypothesis that the process of hairpin unfolding can increase the time of translocation from the A to P ribosome site of the codon 5' to the hairpin, thus decreasing the probability of translational error (the latter would likely occur more frequently in the codons translated by minor tRNAs).

Mechanism of codon recognition by transfer RNA and codon-induced tRNA association

The steps of UUC recognition by tRNAPhe were analysed by temperature-jump measurements. At ion concentrations close to physiological conditions we found three relaxation processes, which we assigned to (1) formation of codon-anticodon complexes, (2) a conformational change of the anticodon loop coupled with Mg2+ binding, and (3) codon-induced association of tRNA. The relaxation data were evaluated both by the usual procedure (fitting the exponentials evaluated from the individual experiments of a set to a reaction model) and by "global fitting", i.e. fitting a set of relaxation curves obtained at various concentrations directly to a reaction model, thus leaving out the intermediate exponential fitting step. The data can be represented quantitatively by a three-step model: the codon binds to the anticodon at a rate of 4 X 10(6) to 6 X 10(6) M-1S-1 as is usual for the formation of oligomer helices; the conformation change of the anticodon loop is associated with inner sphere complexation of Mg2+ at a rate of 10(3) S-1; the codon-tRNA complexes form dimers at a rate of 5 X 10(6) to 15 X 10(6) M-1S-1. A similar mechanism is found for the binding of the wobble codon UUU to tRNAPhe at increased concentrations of Mg2+. Measurements at different Mg2+ concentrations demonstrate the distinct role of this ion in the codon recognition and the codon-induced tRNA dimerization. We propose a simple mechanism, based upon the special properties of magnesium ions, for long-distance transfer of reaction signals along nucleic acid chains.

Self base pairing in a complementary deoxydinucleoside monophosphate duplex: crystal and molecular structure of deoxycytidylyl-(3'-5')-deoxyguanosine

The molecular structure of ammonium deoxycytidylyl-(3'-5')-deoxyguanosine, crystallized from aqueous acetone near pH 4, was determined for X-ray diffraction data. The crystals were tetragonal, space group P43212 with a = b = 11.078 (1) A and c = 45.826 (4) A. The structure was solved by tangent expansion of phases based on a derived phosphorus position and refined to R = 0.060 by full matrix least squares. Molecules related by a 2-fold symmetry axis are connected by hydrogen bonds between the bases and form parallel right-handed duplexes. Pairs of cytosines share a proton at N(3) and are joined by three hydrogen bonds: N(4)-H...O(2)...H-N(4), and N(3)-H...N(3). Guanines are joined by two hydrogen bonds: N(2)-H...N(3) and N(3)...H-N(2). Base-stacking interactions within the duplex are weak with the cytosine and guanine ring planes inclined at 24 degrees to each other in each monomer. Despite the unusual arrangement of the molecules, the sugar phosphate backbone has the g-g- conformation normally associated with right-handed double helical structures. Conformational parameters of the nucleosides are also typical with both sugars C(2')-endo and glycosidic torsion angles 55 degrees for cytidine and 94 degrees for guanosine. The bonding geometry of the bases is influenced by hydrogen bonding and charge-transfer networks in the crystal lattice. The solvent molecules interact with the dimer in three fused circular hydrogen bonding domains with a single disordered ammonium cation per d(CpG) dimer. Parallels with the formation of self base pairs and their implications in molecular biology are discussed.

Characterization of mutants of Escherichia coli with an increased control of translation fidelity

Neomycin-resistant mutants of Escherichia coli K12 were selected on a minimal succinate medium containing neomycin. In an in vitro poly(U)-dependent protein synthesizing assay, the ribosomes from the mutant strains showed lower levels of misreading than wild-type ribosomes in the presence of neomycin or other error-promoting aminoglycoside antibiotics or ethanol. The mutation was shown to affect a component of the 30S subunit and to facilitate the dissociation of ribosomes into subunits. It is suggested that an impairment in the subunit interaction may be responsible for the observed restriction of the stimulation of misreading.

On the origin of biological systems and the role of poly-nucleotides -- the initiation of evolution, the structural basis of the genetic code and the mechanism of protein biosynthesis

There is much information on the nature and function of biological systems in the structures of the small molecules that affect them and in the biosynthetic and other reactions in which they are involved. Combining this with biochemical and polynucleotide sequence information allows us to derive explanations for a number of biological problems that earlier were unclear or even quite obscure. Thus polynucleotide systems give a good account of the origin of life, of the genetic code and of the function of the ribosomal mechanism of protein biosynthesis. It is apparent that polynucleotides play a more important role than has been fully appreciated.

Speed-accuracy relationships during in vitro and in vivo protein biosynthesis

Poly U-directed incorporation of phenylalanine and leucine into polypeptide has been described in at least 50 papers since 1961. In general, high translation activities are associated with high accuracies, and vice-versa. Moreover, a vast body of independent experimental data (effect of ethanol, temperature, urea, aminoglycosides, etc... on protein synthesis) put together here suggests that, in many circumstances, speed and accuracy of elongation are correlated. This result is to be contrasted with the view that the speed and the fidelity of protein synthesis are two opposing parameters. In this report, recent experimental data on the nature and effect of ribosomal ambiguity (ram) and streptomycin resistance (Strr) mutations are reexamined. Models on the action of streptomycin and other misreading-inducing antibiotics, as well as long-standing ideas on the control of misreading in mammalian systems are critically evaluated. An explanation is provided for the long-befuddling data on the action of gentamicin.

Leaky +1 and -1 frameshift mutations at the same site in a yeast mitochondrial gene

Two mutations in a mitochondrial structural gene, which cause leaky premature polypeptide chain termination and leaky growth, are +1 and -1 frameshifts in the same run of five T residues. The partial restoration of reading frame is probably due to ribosomal frameshifting at this site, and may be promoted by the unique structure of the yeast mitochondrial t RNAPhe.

Free-energy dissipation constraints on the accuracy of enzymatic selections

A bacterium incorporates amino acids into protein with an error frequency close to one in three thousand (Edelman & Gallant, 1977). Nevertheless, the structural differences between related amino acids are so small that it is difficult to see how they can be distinguished from each other with such accuracy (see, for example, Pauling, 1958).

Indeed, the selection of amino acids during protein synthesis is carried out twice: first by the aminoacyl-tRNA synthetases and then by the codon-programmed ribosome. Each of these substrate selections is in fact a double selection. In the case of the synthetase both a particular amino acid and a corresponding cognate tRNA must be chosen to form the aminoacyl-tRNA. On the ribosome, the aminoacyl-tRNA must be matched with a cognate codon, and then the mRNA must be advanced by exactly one codon length to position the next codon in the appropriate ribosome site so that it too can be translated.