Structure of ribosome-bound messenger RNA as revealed by enzymatic accessibility studies

Post-transcriptional control of gene expression: bacterial mRNA degradation

Many biological processes cannot be fully understood without detailed knowledge of RNA metabolism. The continuous breakdown and resynthesis of prokaryotic mRNA permit rapid production of new kinds of proteins. In this way, mRNA levels can regulate protein synthesis and cellular growth. Analysing mRNA degradation in prokaryotes has been particularly difficult because most mRNA undergo rapid exponential decay. Prokaryotic mRNAs differ in their susceptibility to degradation by endonucleases and exonucleases, possibly because of variation in their sequencing and structure. In spite of numerous studies, details of mRNA degradation are still largely unknown. This review highlights those aspects of mRNA metabolism which seem most influential in the regulation of gene expression.

Multiscale modeling of metabolism and macromolecular synthesis in E. coli and its application to the evolution of codon usage

Biological systems are inherently hierarchal and multiscale in time and space. A major challenge of systems biology is to describe biological systems as a computational model, which can be used to derive novel hypothesis and drive experiments leading to new knowledge. The constraint-based reconstruction and analysis approach has been successfully applied to metabolism and to the macromolecular synthesis machinery assembly. Here, we present the first integrated stoichiometric multiscale model of metabolism and macromolecular synthesis for Escherichia coli K12 MG1655, which describes the sequence-specific synthesis and function of almost 2000 gene products at molecular detail. We added linear constraints, which couple enzyme synthesis and catalysis reactions. Comparison with experimental data showed improvement of growth phenotype prediction with the multiscale model over E. coli's metabolic model alone. Many of the genes covered by this integrated model are well conserved across enterobacters and other, less related bacteria. We addressed the question of whether the bias in synonymous codon usage could affect the growth phenotype and environmental niches that an organism can occupy. We created two classes of in silico strains, one with more biased codon usage and one with more equilibrated codon usage than the wildtype. The reduced growth phenotype in biased strains was caused by tRNA supply shortage, indicating that expansion of tRNA gene content or tRNA codon recognition allow E. coli to respond to changes in codon usage bias. Our analysis suggests that in order to maximize growth and to adapt to new environmental niches, codon usage and tRNA content must co-evolve. These results provide further evidence for the mutation-selection-drift balance theory of codon usage bias. This integrated multiscale reconstruction successfully demonstrates that the constraint-based modeling approach is well suited to whole-cell modeling endeavors.

Regulation of pyrimidine biosynthetic gene expression in bacteria: repression without repressors

SUMMARY

DNA-binding repressor proteins that govern transcription initiation in response to end products generally regulate bacterial biosynthetic genes, but this is rarely true for the pyrimidine biosynthetic (pyr) genes. Instead, bacterial pyr gene regulation generally involves mechanisms that rely only on regulatory sequences embedded in the leader region of the operon, which cause premature transcription termination or translation inhibition in response to nucleotide signals. Studies with Escherichia coli and Bacillus subtilis pyr genes reveal a variety of regulatory mechanisms. Transcription attenuation via UTP-sensitive coupled transcription and translation regulates expression of the pyrBI and pyrE operons in enteric bacteria, whereas nucleotide effects on binding of the PyrR protein to pyr mRNA attenuation sites control pyr operon expression in most gram-positive bacteria. Nucleotide-sensitive reiterative transcription underlies regulation of other pyr genes. With the E. coli pyrBI, carAB, codBA, and upp-uraA operons, UTP-sensitive reiterative transcription within the initially transcribed region (ITR) leads to nonproductive transcription initiation. CTP-sensitive reiterative transcription in the pyrG ITRs of gram-positive bacteria, which involves the addition of G residues, results in the formation of an antiterminator RNA hairpin and suppression of transcription attenuation. Some mechanisms involve regulation of translation rather than transcription. Expression of the pyrC and pyrD operons of enteric bacteria is controlled by nucleotide-sensitive transcription start switching that produces transcripts with different potentials for translation. In Mycobacterium smegmatis and other bacteria, PyrR modulates translation of pyr genes by binding to their ribosome binding site. Evidence supporting these conclusions, generalizations for other bacteria, and prospects for future research are presented.

A codon window in mRNA downstream of the initiation codon where NGG codons give strongly reduced gene expression in Escherichia coli

The influences on gene expression by codons at positions +2, +3, +5 and +7 downstream of the initiation codon have been compared. Most of the +2 codons that are known to give low gene expression are associated with a higher expression if placed at the later positions. The NGG codons AGG, CGG, UGG and GGG, but not GGN or GNG (where N is non-G), are unique since they are associated with a very low gene expression also if located at positions +2, +3 and +5. All codons, including NGG, give a normal gene expression if placed at positions +7. The negative effect by the NGG codons is true for both the lacZ and 3A' model genes. The low expression is suggested to originate at the translational level, although it is not the result of mRNA secondary structure or a lowered intracellular mRNA pool.

Mean-field approaches to the totally asymmetric exclusion process with quenched disorder and large particles

The process of protein synthesis in biological systems resembles a one-dimensional driven lattice gas in which the particles (ribosomes) have spatial extent, covering more than one lattice site. Realistic, nonuniform gene sequences lead to quenched disorder in the particle hopping rates. We study the totally asymmetric exclusion process with large particles and quenched disorder via several mean-field approaches and compare the mean-field results with Monte Carlo simulations. Mean-field equations obtained from the literature are found to be reasonably effective in describing this system. A numerical technique is developed for computing the particle current rapidly. The mean-field approach is extended to include two-point correlations between adjacent sites. The two-point results are found to match Monte Carlo simulations more closely.

Influences on translation initiation and early elongation by the messenger RNA region flanking the initiation codon at the 3' side

The downstream region (DR) located immediately after the initiation codon acts as a translational enhancer and depending on its sequence gene expression can vary considerably. In order to determine the influence of the DR on the apparent translation initiation, we have analyzed several naturally occurring DRs (a stretch of five codons) in a lacZ reporter gene. The efficiency of expression, associated with these DRs did not show any correlation to the expression levels connected with the natural genes. Changes of the iso-codon composition in the DR, thus maintaining the amino acid sequence in the gene product, gave significant variations in gene expression. Thus, the messenger RNA base sequence, and not the encoded amino acid sequence, in the early coding region is the determinant for the apparent efficiency of translation initiation and/or early elongation.

Comparative mutational analysis of cis-acting RNA signals for translational frameshifting in HIV-1 and HTLV-2

Human immunodeficiency virus type 1 (HIV-1) and human T cell leukemia virus type II (HTLV-2) use a similar mechanism for -1 translational frameshifting to overcome the termination codon in viral RNA at the end of the gag gene. Previous studies have identified two important RNA signals for frameshifting, the slippery sequence and a downstream stem-loop structure. However, there have been somewhat conflicting reports concerning the individual contributions of these sequences. In this study we have performed a comprehensive mutational analysis of the cis-acting RNA sequences involved in HIV-1 gag-pol and HTLV-2 gag-pro frameshifting. Using an in vitro translation system we determined frameshifting efficiencies for shuffled HIV-1/HTLV-2 RNA elements in a background of HIV-1 or HTLV-2 sequences. We show that the ability of the slippery sequence and stem-loop to promote ribosomal frameshifting is influenced by the flanking upstream sequence and the nucleotides in the spacer element. A wide range of frameshift efficiency rates was observed for both viruses when shuffling single sequence elements. The results for HIV-1/HTLV-2 chimeric constructs represent strong evidence supporting the notion that the viral wild-type sequences are not designed for maximal frameshifting activity but are optimized to a level suited to efficient viral replication.

A tripeptide sequence within the nascent DaaP protein is required for mRNA processing of a fimbrial operon in Escherichia coli

The biogenesis of F1845 fimbriae, a member of the Dr family of Escherichia coli adhesins, is regulated by endonucleolytic cleavage of the daaABCDPE primary transcript and differential stability of the resulting cleavage products. Processing of daa mRNA is dependent upon translation of a small open reading frame, designated daaP, which flanks the daa processing site. Here, we demonstrate that daa mRNA processing is directly coupled to daaP translation. Cleavage of the daaA-E mRNA was shown to require the tripeptide Gly-Pro-Pro (GPP), encoded by daaP codons 49-51 downstream of the processing site. Processing also required active translation through RNA located upstream of the processing site; however, processing did not depend on the amino acid sequence encoded by the region of daaP upstream of the processing site. Finally, determination of the processing site was shown to involve its location relative to the codons encoding the GPP tripeptide. These data show that translation of daaP is required in cis to promote RNA processing. These data suggest a model involving interaction of the nascent GPP tripeptide portion of the DaaP polypeptide with the ribosome, triggering cleavage of the associated mRNA at a fixed distance upstream. A model of active involvement of the ribosome in this process is proposed.

Ribosome traffic in E. coli and regulation of gene expression

The ribosome traffic during translation of E. coli coding sequences was simulated, assuming that the rate of translation of individual codons is limited by the cognate tRNA availability. Actual translation rates were taken from Solomovici et al. (J. theor. Biol. 185, 511-521, 1997). The mean translation rates of the 4271 sequences cover a broad, two-fold range, whereas the local rate of translation along messengers varies three-fold on average. The simulation allows one to sketch the ribosome traffic on the polysome, in particular by providing the extent of mRNA sequences uncovered between consecutive ribosomes and the time during which these sequences are exposed. These parameters may participate in the control of mRNA stability and transcriptional polarity. By averaging the translation rates in a 17-codon window, assumed to be the sequence covered by a translating ribosome, and sliding this window along a given coding sequence, the addresses KMAX and KMIN, and the times TMAX and TMIN of respectively the slowest and the fastest translated window were determined. It is shown that under the assumptions made, TMAX sets the number of proteins translated from a given mRNA molecule per unit time, in case the delay between consecutive translation starts is below TMAX. Both windows display two strong biases, one as expected on the usage of codon frequencies, and the other surprisingly on the occurrence of amino acids.

Decay of ermC mRNA in a polynucleotide phosphorylase mutant of Bacillus subtilis

ermC mRNA decay was examined in a mutant of Bacillus subtilis that has a deleted pnpA gene (coding for polynucleotide phosphorylase). 5'-proximal RNA fragments less than 400 nucleotides in length were abundant in the pnpA strain but barely detectable in the wild type. On the other hand, the patterns of 3'-proximal RNA fragments were similar in the wild-type and pnpA strains. Northern blot analysis with different probes showed that the 5' end of the decay intermediates was the native ermC 5' end. For one prominent ermC RNA fragment, in particular, it was shown that formation of its 3' end was directly related to the presence of a stalled ribosome. 5'-proximal decay intermediates were also detected for transcripts encoded by the yybF gene. These results suggest that PNPase activity, which may be less sensitive to structures or sequences that block exonucleolytic decay, is required for efficient decay of specific mRNA fragments. However, it was shown that even PNPase activity could be blocked in vivo at a particular RNA structure.

Cleavage of 16S rRNA within the ribosome by mRNA modified in the A-site codon with phenanthroline-Cu(II)

Cleavage of 16S rRNA was obtained through mRNA modified at position +5 with the chemical cleavage agent 1,10-o-phenanthroline. In the presence of Cu2+, and after addition of reducing agent to the modified mRNA-70S complex, cleavage of proximal nucleotides within the 16S rRNA occurred. Primer extension analysis of 16S rRNA fragments revealed that nucleotides 528-532, 1196, and 1396-1397 were cleaved. Nucleotides 1053-1055 were also cleaved but did not show the same level of specificity as the former. These results provide evidence that at some point in the translation process these regions are all within 15 A of position +5, the A-site codon, on the mRNA.

Ribosomal decoding processes at codons in the A or P sites depend differently on 2'-OH groups

The importance of 2'-OH groups of codons for binding of cognate tRNAs to ribosomal P and A sites was analyzed applying the following strategy. An mRNA of 41 nucleotides was synthesized with the structure C16-GAA-UUC-GUC-C16 coding for glutamic acid (E), phenylalanine (F) and valine (V), respectively, in the middle (EFV-mRNA). A second template, the E(dF)V-mRNA, was identical except that it carried a deoxyribo-codon-dUdUdC- for phenylalanine. tRNA binding to the P site is totally insensitive to the presence or absence of the 2'-OH group of the P-site codon, and tRNA binding to the P site is also not affected if the A-site codon lacks the 2'-OH groups. However, binding is impaired if the deoxy-codon is present at the E site. In sharp contrast, the A-site binding of Ac-aminoacyl-tRNA was severely reduced in the presence of the deoxy-codon at the A site as well as at the P site. The results demonstrate that the correctness of base pairing is also "sensed" via a correct sugar structure of the codon, e.g. positioning of the sugar pucker (2'-OH), during the decoding process at the A site (elongation) but not during the decoding at the P site (initiation).

Recognition of the mRNA selenocysteine insertion sequence by the specialized translational elongation factor SELB

In Escherichia coli the unusual amino acid selenocysteine is incorporated cotranslationally at an in-frame UGA codon. Incorporation of selenocysteine relies, in part, on the interaction between a specialized elongation factor, the SELB protein, and a cis-acting element within the mRNA. Boundary and toeprint experiments illustrate that the SELB-GTP-Sec-tRNA(Sec) ternary complex binds to the selenoprotein encoding mRNAs fdhF and fdnG, serving to increase the concentration of SELB and Sec-tRNA(Sec) on these mRNAs in vivo. Moreover, toeprint experiments indicate that SELB recognizes the ribosome-bound message and that, upon binding, SELB may protrude out of the ribosomal-mRNA track so as to approach the large ribosomal subunit. The results place the mRNA-bound SELB-GTP-Sec-tRNA(Sec) ternary complex at the selenocysteine codon (as expected) and suggest a mechanism to explain the specificity of selenocysteine insertion. Cis-acting mRNA regulatory elements can tether protein factors to the translation complex during protein synthesis.

Nature of the ribosomal mRNA track: analysis of ribosome-binding sites containing different sequences and secondary structures

The ribosomal mRNA track was investigated by toeprinting 30S ribosomes, in the presence or absence of tRNA, using a variety of different ribosome-binding sites. We found that: (1) the ribosome, by itself, recognizes the mRNA translational initiation site; (2) the ribosomal mRNA track makes extensive contact with mRNA independent of tRNA and the start codon; (3) ribosome-mRNA complexes are less stable than complexes containing tRNA; and (4) toeprinting can be used to analyze the contour of the ribosomal mRNA track, yielding information on its "height" as well as its "length" dimension. Examination of several ribosome-binding sites, including those containing very stable secondary structure, indicated that the "height" of the mRNA track is quite roomy, while the nucleotide distance between the site of Shine-Dalgarno annealing, the P site, and the 3'-edge of the mRNA track is fixed. The data suggest a mechanism for tethering regulatory elements to the ribosome during translation.

Frameshifting in the expression of the E. coli trpR gene occurs by the bypassing of a segment of its coding sequence

The E. coli trpR gene encodes the 108 amino acid long trp repressor. We have previously shown that a +1 frameshifting event occurs during the expression of trpR. Here we show that the transition from the 0 to the +1 frame of trpR occurs by the bypassing of a 55 nt long segment of the trpR+1-lacZ mRNA. This bypassing event is not pretranslational, and it probably takes place during translation. Two adjacent elements are required: a specific sequence of trpR, which must be preceded by a nonspecific 5' end longer than 10 translatable codons. Unique to trpR-lacZ bypassing is that the 55 nt long region must be translated in frame 0 to enable bypassing into the +1 frame. Translational bypassing as a newly discovered mechanism of gene expression is discussed, and the possible existence of translational introns is suggested.

The mRNA binding track in the Escherichia coli ribosome for mRNAs of different sequences

Interactions between mRNA and rRNA on the 30S ribosomal subunit or 70S ribosome have been determined by photochemical cross-linking experiments using synthetic mRNA analogs substituted with 4-thiouridine. A set of RNA molecules containing different sequences has been used to determine the extent to which binding contacts are sequence dependent. The 16S rRNA and 23S rRNA nucleotides that form a part of the binding site have been identified by reverse transcription. The nucleotides are U1381, G1338, G1300, G1156, A845, U723, G693, A532, G497, U420, G413/A412, and G436 of 16S rRNA and U887 of 23S rRNA. Several additional nucleotides (U1065 of 23S rRNA and A1227, G818, G524, and G423 of 16S rRNA) are seen for some, but not all, of the mRNAs. Results obtained with two mRNAs containing the Shine-Dalgarno sequence were similar to those obtained with mRNAs lacking the Shine-Dalgarno sequence. Eight of these cross-linking sites were also seen when a mixture of RNA was used in which there are 12 random nucleotides preceding and seven random nucleotides succeeding an AUG codon. These results indicate that to a large extent placement of the mRNA in the ribosome does not depend upon its primary sequence.

Mutational analysis of an inherently defective translation initiation site

In a reverse of many studies of translational initiation sites, we have explored the basis for the inactivity of an apparently defective initiation site. Gene VII of the filamentous phage f1 has a translational start site with highly unusual functional properties and a sequence dissimilar to a prokaryotic ribosome binding site. The VII site shows no activity in assays of independent initiation, even in a deletion series designed to remove potentially interfering RNA secondary structure. Activity from the VII site is only observed if the site is coupled to a source of translation immediately upstream, but its efficiency is low at a one-nucleotide spacing from the stop codon of the upstream cistron and extremely sensitive to the distance between the stop codon and the gene VII AUG. These and other atypical characteristics of coupling distinguish the VII site from most coupled initiation sites. To identify the pattern of nucleotide substitutions that give the VII site the capacity for independent initiation, a series of designed and random point mutations were introduced in the sequence. Improving the Shine-Dalgarno complementarity from GG to GGAG or GGAGG made activity detectable, but at only low levels. Random substitutions, each increasing activity above background by a small increment, were found at 16 positions throughout the region of ribosome contact. These substitutions lengthened the Shine-Dalgarno complementarity or changed the G and C residues present in the wild-type site to A or T. Significant activity was not observed unless a strong Shine-Dalgarno sequence and a number of the up-mutations were present together. The nature and distribution of the substitutions and their agreement with the known preferences for nucleotides in initiation sites provide evidence that the VII site's major defect is its primary sequence overall. It appears to lack the specialized sequence required to bind free 30 S ribosomes, and thus depends on the translational coupling process to give it limited activity.

Recognition of correct reading frame by the ribosome

The translation frame-monitoring mechanism has been suggested earlier, based on transient complementary contacts, between mRNA and rRNA. Recent studies related to the frame-monitoring mechanism are reviewed. The mechanism is well supported by both new experimental and sequence analysis data. Experiments are suggested for further elucidation of the structural details of the mRNA-rRNA interaction in the ribosome.

Chloramphenicol-induced stabilization of cat messenger RNA in Bacillus subtilis

The expression of the chloramphenicol-inducible chloramphenicol-acetyltransferase gene (cat), encoded on Staphylococcus aureus plasmid pUB112, is regulated via a translational attenuation mechanism. Ribosomes, which are arrested by chloramphenicol during synthesis of a short leader peptide, activate catmRNA translation by opening a 5'-located stem-loop structure, thus setting free the cat ribosome-binding site. We have determined the 5' and 3' ends of catmRNA and analysed its stability in Bacillus subtilis. In the absence of the antibiotic, the half-life of catmRNA is shorter than 0.5 min; it is enhanced to about 8 min by sub-inhibitory concentrations of the drug. No decay intermediates of catmRNA could be detected, indicating a very fast degradation after an initial rate-limiting step. ochre nonsense mutations in the 5' region of the cat structural gene, which eliminate catmRNA translation, did not affect its chloramphenicol-induced stabilization. Mutations in the leader-peptide coding region, which abolish ribosome stalling and, therefore, cat gene induction, also eliminate catmRNA stabilization. We conclude that catmRNA is stabilized on induction by a chloramphenicol-arrested ribosome, which physically protects a nuclease-sensitive target site in the 5' region of catmRNA against exo- or endonucleolytic initiation of degradation. This protection is analogous to ermA and ermC mRNA and seems to reflect a general mechanism for stabilization of mRNA derived from inducible antibiotic resistance genes in B. subtilis.

Spatial organization of template polynucleotides on the ribosome determined by fluorescence methods

The spatial organization of template polynucleotides on the ribosome and the dynamics of their interaction with 30 S subunits have been studied by fluorescence spectroscopy. The topography of the mRNA in the ribosome has been determined using singlet-singlet energy transfer. This method has allowed us to estimate distances between donors and acceptors of energy which have been linked to the terminal residues of template polynucleotides (poly- and oligo(U) and oligo(A] and 16 S RNA or to SH-groups of ribosomal proteins S1 and S8. The dynamics of mRNA-ribosome interaction have been investigated by the fluorescence stopped-flow technique. It has been shown that the binding to the 30 S subunit of poly(U) with length much shorter (16 nucleotides) than that covered by the ribosome is greatly enhanced by protein S1. However, the final position of oligo(U)16 on the 30 S subunit, which probably includes the ribosomal decoding site, proves to be quite different from that occupied by oligo(U)16 on a free protein S1. Interaction of oligo- and poly(U) with the 30 S subunit occurs in at least two steps: the first one is as fast as the interaction of poly(U) with free S1, whereas the second step represents a first-order reaction. Therefore, the second step may reflect some rearrangement of the template in the ribosome after its primary binding. It is suggested that protein S1 in some cases may fulfill the role of a transient binding site for mRNA in the course of its interaction with the ribosome. The general shape of the template in the mRNA binding region of the ribosome has been studied using various synthetic ribopolynucleotides and has been shown to be similar. It can be represented by a loop(s) or "U-turn(s)". On the basis of estimation of distances from the ends of poly(U) to some well-localized points on the 30 S ribosomal surface, a tentative model of mRNA path through the ribosome is proposed.

The function of the translating ribosome: allosteric three-site model of elongation

During the last decade, a new model for the ribosomal elongation cycle has emerged. It is based on the finding that eubacterial ribosomes possess 3 tRNA binding sites. More recently, this has been confirmed for archaebacterial and eukaryotic ribosomes as well, and thus appears to be a universal feature of the protein synthetic machinery. Ribosomes from organisms of all 3 kingdoms harbor, in addition to the classical P and A sites, an E site (E for exit), into which deacylated tRNA is displaced during translocation, and from which it is expelled by the binding of an aminoacyl-tRNA to the A site at the beginning of the subsequent elongation round. The main features of the allosteric 3-site model of ribosomal elongation are the following: first, the third tRNA binding site is located 'upstream' adjacent to the P site with respect to the messenger, ie on the 5'-side of the P site. Second, during translocation, deacylated tRNA does not leave the ribosome from the P site, but co-translocates from the P site to the E site--when peptidyl-tRNA translocates from the A site to the P site. Third, deacylated tRNA is tightly bound to the E site in the post-translocational state, where it undergoes codon--anticodon interaction. Fourth, the elongating ribosome oscillates between 2 main conformations: (i), the pre-translocational conformer, where aminoacyl-tRNA (or peptidyl-tRNA) and peptidyl-tRNA (or deacylated tRNA) are firmly bound to the A and P sites, respectively; and (ii), the post-translocational conformer, where peptidyl-tRNA and deacylated tRNA are firmly bound to the P and E sites, respectively. The transition between the 2 states is regulated in an allosteric manner via negative cooperatively. It is modulated in a symmetrical fashion by the 2 elongation factors Tu and G. An elongating ribosome always maintains 2 high-affinity tRNA binding sites with 2 adjacent codon--anticodon interactions. The allosteric transition from the post- to the pre-translocational state is involved in the accuracy of aminoacyl-tRNA selection, and the maintenance of 2 codon--anticodon interactions helps to keep the messenger in frame during translation.

How does the mRNA pass through the ribosome?

A working model of the mRNA path through the ribosome is proposed. According to the model, the template goes around the small ribosomal subunit along the region where its 'head' is separated from other parts of the subunit. The 5'-end of the mRNA fragment covered by the ribosome is located near the 3'-terminus of 16S rRNA, whereas the 3'-terminal residues of the fragment are situated on the outer surface of the subunit, opposite its 'side ledge'. When associated with the 50S subunit, the 30S subunit is oriented in such a manner that the decoding center faces the L7/L12 stalk. Implications of the proposed working model of the mRNA topography for the function of the ribosome are discussed.

Sites of contact of mRNA with 16S rRNA and 23S rRNA in the Escherichia coli ribosome

The locations of close encounter between ribosomal RNA (rRNA) and messenger RNA (mRNA) were determined by photochemical cross-linking experiments that employ an artificial mRNA, 51 nucleotides long, containing 14 U residues that were randomly substituted by 1-4 4-thiouridine (s4U) residues. The mRNA was bound to 70S ribosomes or 30S subunits and then was irradiated at 366 nm to activate cross-linking between the s4U residues and rRNA. Cross-linking occurred to both 16S rRNA and 23S RNA. The rRNA was then analyzed by a series of reverse transcriptase experiments to determine the locations of cross-linking. Twelve sites in the 16S rRNA and two sites in the 23S rRNA have been detected. In the 16S rRNA, two of the sites (U1381, C1395) are in the middle part of the secondary structure close to position C1400, and the remaining sites (G413, U421, G424; A532; G693; U723; A845; G1131/C1132; G1300; G1338) are distributed between six regions that are peripheral in the secondary structure. In the 23S rRNA, one site (U1065) is located in the GTPase center close to A1067, the site of thiostrepton-resistance methylation in domain II, and the other site (U887) is located a short distance away also in domain II. The distribution of these rRNA sites in the ribosome specifies an mRNA track that is consistent with other information. In addition, some of the contact points represent new constraints for the three-dimensional folding of the rRNA.

Suppression and the code: beyond codons and anticodons

Specificity and accuracy in the decoding of genetic information during mRNA-programmed, ribosome-dependent polypeptide synthesis (translation) involves more than just hydrogen bonding between two anti-parallel trinucleotides, the mRNA codon and the tRNA anticodon. Other macromolecules are also involved, and translational suppression has been and continues to be an appropriate and effective way to identify them, as well as other parts of mRNA and tRNA, and to elucidate the structural determinants of their functions and interactions. Experimental results are presented that bear upon codon context effects, the role of tRNA structural features in aminoacyl-tRNA selection and in codon selection (reading-frame maintenance), determinants of tRNA identity, elongation factor suppressor mutants, and termination codon recognition by the ribosomal RNA of the small subunit. The examples presented illustrate the complexity of the decoding process and the interconnectedness of translational macromolecules in achieving specificity and accuracy in polypeptide synthesis.

A nascent peptide is required for ribosomal bypass of the coding gap in bacteriophage T4 gene 60

Bacteriophage T4 DNA topoisomerase gene 60 contains a 50 nucleotide untranslated region within the coding sequence of its mRNA. Translational bypass of this sequence by elongating ribosomes has been postulated for the mode of synthesis of an 18 kd polypeptide specified by the split coding segments. Ribosome bypass of the untranslated region also occurs when a segment of gene 60 is fused to lacZ and expressed in E. coli. The efficiency of bypass in these gene 60-lacZ fusions approaches 100%. Here, mutations that delete, insert, or substitute nucleotides from gene 60-lacZ fusions are examined. Essential features necessary for high level gap bypass emerging from this analysis are a cis-acting nascent peptide sequence, a short duplication bordering the gap, and a stop codon contained in a stem-loop structure at the 5' junction of the gap.

The initiation of translation in E. coli: apparent base pairing between the 16srRNA and downstream sequences of the mRNA

Bacteriophage T7's gene 0.3, coding for an antirestriction protein, possesses one of the strongest translation initiation regions (TIR) in E. coli. It was isolated on DNA fragments of differing length and cloned upstream of the mouse dihydrofolate reductase gene in an expression vector to control the translation of this gene's sequence. The TIR's efficiency was highly dependent on nucleotides +15 to +26 downstream of the gene's AUG. This sequence is complementary to nucleotides 1471-1482 of the 16srRNA. Similar sequences complementary to this rRNA region are present in other efficient TIRs of the E. coli genome and those of its bacteriophages. There seems to be a correlation between this sequence homology and the efficiency of the initiation signals. We propose that this region specifies a stimulatory interaction between the mRNA and 16srRNA besides the Shine-Dalgarno interaction during the translation initiation step.

Site-directed cross-linking of mRNA analogues to the Escherichia coli ribosome; identification of 30S ribosomal components that can be cross-linked to the mRNA at various points 5' with respect to the decoding site

Three different mRNA analogues (28 to 34 nucleotides long) were prepared by T7 transcription from synthetic DNA templates. Each message contained the sequence ACC-GCG (coding for threonine and alanine, respectively), together with a single thio-U residue located at a variable position on the 5'-side of these coding triplets. A photo-reactive group was introduced by substitution of the thio-U with 4-azidophenacyl bromide. The messages were bound to E. coli 70S ribosomes in the presence of the appropriate tRNA-Thr or tRNA-Ala, and the azidophenyl group was photoactivated. Cross-linking was found to occur exclusively within the 30S subunit, with the 32P-label in the cross-linked mRNA being divided roughly equally between 30S ribosomal proteins and 16S RNA. Immunological analysis of the cross-linked proteins showed that, in the presence of either tRNA species, protein S7 was the primary target, whereas in the absence of tRNA only small amounts of protein S21 were cross-linked. The cross-link site to 16S RNA lay in all cases very close to its extreme 3'-terminus. These data indicate that the outgoing message leaves the cleft of the 30S subunit in a "northerly" direction.

Erythromycin-induced ribosome stall in the ermA leader: a barricade to 5'-to-3' nucleolytic cleavage of the ermA transcript

The Staphylococcus aureus ermA gene, whose product confers resistance to the macrolide-lincosamide-streptogramin B family of antibiotics, is induced at the level of translation by nanomolar concentrations of erythromycin. Erythromycin also specifically stabilizes ermA transcripts, and the induced stabilization requires in-phase translation of at least one of two small leader peptides in the 5' leader region of the transcript. Erythromycin-induced mRNA stabilization was tested in three constructions in which the ermA transcript was elongated by making insertions at the ermA transcription start. Whereas mRNA downstream of the leader peptide is stabilized by erythromycin, mRNA upstream is not. In the presence of erythromycin, specific mRNA decay intermediates in both the extended ermA genes and the wild-type ermA gene were detected by both Northern blotting and S1 nuclease mapping. The 5' ends of the intermediates map to the sequences that encode each of the two ermA leader peptides, suggesting that the intermediates are produced by stalled erythromycin-bound ribosomes acting as barricades to degradation by 5'-to-3' RNases. In addition, whereas erythromycin was found previously to stabilize ermA transcripts only physically, an ermC-cat-86 hybrid transcript was stabilized both physically and functionally by erythromycin.

Mechanism of erythromycin-induced ermC mRNA stability in Bacillus subtilis

In Bacillus subtilis, the ermC gene encodes an mRNA that is unusually stable (40-min half-life) in the presence of erythromycin, an inducer of ermC gene expression. A requirement for this induced mRNA stability is a ribosome stalled in the ermC leader region. This property of ermC mRNA was used to study the decay of mRNA in B. subtilis. Using constructs in which the ribosome stall site was internal rather than at the 5' end of the message, we show that ribosome stalling provides stability to sequences downstream but not upstream of the ribosome stall site. Our results indicate that ermC mRNA is degraded by a ribonucleolytic activity that begins at the 5' end and degrades the message in a 5'-to-3' direction.

Mapping the lacZ ribosome binding site by RNA footprinting

The ribosome binding site of the Escherichia coli lacZ mRNA has been characterized by using an RNA footprinting technique. Purified E. coli 70S ribosomes and fMet-tRNA were incubated with mRNA, and the complex was treated with RNA-reactive reagents or RNases as probes. The protected sites on the mRNA were then mapped by extending a radioactive primer with reverse transcriptase. Dimethyl sulfate, diethyl pyrocarbonate, and 1,10-phenanthroline-copper ion oxidative complex were used as reagent probes; they detected interaction sites within the ribosome binding site. A region of approximately 35 nucleotides was protected by the ribosome, specifically across the Shine-Dalgarno region, around the fMet initiation codon, and at a region 7-12 nucleotides distal to the fMet codon. In addition, an enhanced reaction occurred between the fMet codon and the distal site. These results imply an internally selective interaction between the ribosome and the mRNA sequence. The enhanced reactivity of a site distal to the initiation site--flanked by the AUG codon and a site previously identified as conserved in a study of initiation sequences--may indicate a region where the mRNA is specifically exposed.

ermC leader peptide. Amino acid sequence critical for induction by translational attenuation

The ermC mRNA leader segment, which encodes a 19 amino acid leader peptide, MGIFSIFVISTVHYQPNKK, plays a key role in regulating expression of the ErmC methylase. The contribution of specific leader peptide amino acid residues to induction of ermC was studied using a model system in which the ErmC methylase was translationally fused to Escherichia coli beta-galactosidase as indicator gene. Codons of the ermC leader peptide were altered systematically by replacement of leader DNA segments with double-stranded DNA constructed from chemically synthesized oligonucleotides. Missense mutations that resulted in reduced efficiency of induction involved codons for amino acid residues 5 to 9 (-SIFVI-). Nonsense mutations causing termination of the leader peptide at codons 10 (-S-) or 12 (-V-) remained inducible. These findings suggest that the codons for residues 5 to 9 of the leader peptide comprise the critical region in which ribosomes stall in the presence of erythromycin.

Erythromycin-induced stabilization of ermA messenger RNA in Staphylococcus aureus and Bacillus subtilis

Erythromycin-induced stabilization of ermA mRNA was studied in Staphylococcus aureus, its original host background, and in Bacillus subtilis, subcloned on plasmid vectors. By RNA blot analysis it was shown that 40 nM-erythromycin specifically increased the chemical half-life of ermA mRNA from 2.5 to 17.5 minutes whereas the half-life of cat-86 mRNA was not increased by erythromycin. While expression of ermA has been shown to be induced by erythromycin at the level of translation, our studies with three ermA constitutive mutants demonstrated that mRNA stabilization in growing cells occurred independently of induced gene expression, suggesting that the stabilized mRNA was not functional for protein synthesis. Studies of ermA/lacZ fusions demonstrated that the 5' end of the mRNA was sufficient to confer stabilization. Translation of specific amino acid codons in a leader peptide located at the extreme 5' end of the mRNA was required for the erythromycin-induced stabilization as a frameshift mutation introduced into the leader peptide determinant abolished stabilization. By S1 mapping, no differences were detected in the length of the 5' or 3' end of ermA mRNA with the addition of erythromycin, indicating that the stabilized transcript was not processed at its ends.

Covalent cross-linking of poly(A) to Escherichia coli ribosomes, and localization of the cross-link site within the 16S RNA

Poly(A) can be cross-linked to E. coli 70S ribosomes in the presence of tRNALys by mild ultraviolet irradiation. The cross-linking reaction is exclusively with the 30S subunit, and involves primarily the RNA moiety. Following a partial nuclease digestion, cross-linked complexes containing poly(A) and fragments of the 16S RNA were isolated by affinity chromatography on oligo(dT)-cellulose. The complexes were purified by gel electrophoresis and subjected to oligonucleotide analysis, which revealed a single cross-link site within positions 1394-1399 of the 16S RNA. The same pattern of cross-linking, at about one-fifth of the intensity, was observed in the absence of tRNALys. The cross-link site to poly(A), together with other sites in the 16S RNA that have been implicated in ribosomal function, is discussed in the framework of our recent model for the three-dimensional structure of 16S RNA; all of the functional sites are clustered together in two distinct groups in the model.

Translational control of phage f1 gene expression by differential activities of the gene V, VII, IX and VIII initiation sites

Phage-specific transcription and subsequent RNA processing in Escherichia coli infected with the filamentous phage (f1, M13, fd) generate a pool of abundant and relatively long-lived phage mRNA species encoding the four adjacent genes V, VII, IX and VIII. Yet the products of gene V and gene VIII are synthesized at much higher levels than the gene VII and gene IX proteins. To ask if the translational initiation sites heading these genes show corresponding differences in activity and/or functional properties, we have purified a number of the phage mRNAs from cells infected with f1 and examined them in in vitro initiation reactions. The ribosome binding patterns obtained for the phage mRNA species and for smaller defined RNA fragments containing selected initiator regions reveal a large range in apparent ribosome binding strengths. The gene V and gene VIII sites are recognized efficiently in each mRNA species in which they are present. Gene IX site activity appears to be limited by local mRNA structure: the site has undetectable or low ribosome binding activity in all of the phage mRNA species, but is at least tenfold more active if the RNA sequences required to form a potential hairpin stem-and-loop 15 nucleotides upstream from the initiator AUG have been removed. The gene VII site shows no evidence of interaction with ribosomes in any phage mRNA or RNA fragment tested. The same striking differences in initiation activity were observed in vivo by cloning small f1 DNA fragments containing gene V or gene VII initiation site sequences to drive beta-galactosidase synthesis. High levels of a gene V-beta-galactosidase fusion protein are initiated at the V site, but no detectable synthesis occurs from the VII site. If the VII site is preceded by all of the information encoding the upstream gene V, however, modest amounts of a fusion protein initiated at the VII site are produced. The overall results, in accord with the observed yields of proteins in the phage-infected cell, provide strong evidence that the properties of these translational initiation sites determine in a significant way the differential expression of phage f1 genes V, VII, IX and VIII.

Relationship between size of mRNA ribosomal binding site and initiation factor function

The rate and the extent of the binding of initiator fMet-tRNA(fMet) to 30S ribosomal subunits in the presence of IF1, IF2 and GTP is either inhibited or slightly stimulated by the presence of IF3 depending on whether the initiation triplet AUG or the polynucleotide poly(AUG) is used as template. To determine the length of the template required for the transition from the AUG- to the poly(AUG)-type of behavior in the presence of IF3, the ribosomal binding of fMet-tRNA was studied in response to AUG triplets extended on either the 5'- or the 3'-side by stretches of homo-oligonucleotides of different lengths. When the binding of fMet-tRNA was studied at equilibrium it was found that IF3 no longer inhibits the amount of ternary complex formed if AUG is extended either 10 nucleotides on the 5'- or 35-40 nucleotides on the 3'-side. When the initial rate of ternary complex formation is considered, shorter extensions (4 nucleotides on the 5'-side or 20-30 nucleotides on the 3'-side) are sufficient to elicit a substantial stimulation by IF3. These results are discussed in relation to the mechanism of action of the initiation factors in the selection of the initiation region of the mRNA by ribosomes.

Effect of premature termination of translation on mRNA stability depends on the site of ribosome release

Translational stop codons were introduced at various locations in the protein-coding regions of the monocistronic bla and ompA gene transcripts of Escherichia coli, and the decay characteristics of the upstream and downstream mRNA segments were analyzed. Premature termination of translation at codon position 26 reduced the stability of both the translated and ribosome-free segments of bla mRNA, whereas release of ribosomes just 30 codons further downstream resulted in normal stability for both segments. Normal stability of an untranslated bla gene mRNA segment required its linkage to a ribosome-bound segment of bla gene mRNA. These findings indicate that depriving an mRNA segment of ribosomes does not necessarily render it more susceptible to degradation. However, premature termination of translation at a location that allows ribosomes to traverse only a short segment of bla mRNA can lead to destabilization of the entire transcript.

Translation framing code and frame-monitoring mechanism as suggested by the analysis of mRNA and 16 S rRNA nucleotide sequences

Protein coding sequences carry an additional message in the form of a universal three-base periodical pattern (G-non-G-N)n, which is expressed as a strong preference for guanines in the first positions of the codons in mRNA and lack of guanines in the second positions. This periodicity appears immediately after the initiation codon and is maintained along the mRNA as far as the termination triplet, where it disappears abruptly. Known cases of ribosome slippage during translation (leaky frameshifts, out-of-frame gene fusion) are analyzed. At the sites of the slippage the G-periodical pattern is found to be interrupted. It reappears downstream from the slippage sites, in a new frame that corresponds to the new translation frame. This suggests that the (G-non-G-N)n pattern in the mRNA may be responsible for monitoring the correct reading frame during translation. Several sites with complementary C-periodical structure are found in the Escherichia coli 16 S rRNA sequence. Only three of them are exposed to various interactions at the surface of the small ribosomal subunit: (517)gcCagCagCegC, (1395)caCacCgcC and (1531)auCacCucC. A model of a frame-monitoring mechanism is suggested based on the weak complementarity of G-periodical mRNA to the C-periodical sites in the ribosomal RNA. The model is strongly supported by the fact that the hypothetical frame-monitoring sites in the 16 S rRNA that are derived from the nucleotide sequence analysis are also the only sites known to be actually involved or implicated in rRNA-mRNA interactions.