Codon usage and secondary structure of MS2 phage RNA.

MS2 is an RNA bacteriophage (3569 bases). The secondary structure of the RNA has been determined, and is known to play an important role in regulating translation. Paired regions of the genome have a higher G+C content than unpaired regions. It has been suggested that this reflects selection for high G+C content to encourage pairing, but a re-analysis of the data together with computer simulation suggest that it is an automatic consequence in any RNA sequence of the way it folds up to minimise its free energy. It has also been suggested that the three registers in which pairing can occur in a coding region are used differentially to optimise the use of the redundancy of the genetic code, but re-analysis of the data shows only weak statistical support for this hypothesis.     

Study of the secondary and tertiary structure of phage MS2 RNA using nucleases and fluorescent dyes specific for secondary structure

The binding of ethidium bromide (EtBr) and acridine orange (AO) to RNA in native state or after hydrolysis by S1 and SV nucleases that specifically split single-stranded and double-stranded segments was studied. Nuclease S1 hydrolysis of RNA does not increase the number of EtBr strong binding sites, Tm and hyperchromic effect being also unchanged. Hydrolysis by double-stranded segments accessible to EtBr is followed by the diminishing of Tm and hyperchromism. A supposition is put forward that the main role in stabilization of the RNA tertiary structure is played by double-stranded segments arranged so that some of them are hidden and do not interact with dyes. One of the possible models may be parallel oriented intramolecular "hair-pins" forming compact "rod-like" structures.     

Comparison of the conformation of RNA from phage MS2 and 16S rRNA. Interaction with dyes specific for the secondary structure of native RNA and RNA subjected to hydrolysis by nuclease S1

The interaction of ethidium bromide (EtBr) with double-stranded (ds), and acridine orange (AO) with single-stranded (ss) fragments of 16S rRNA Escherichia coli in a wide range of ionic strength, at various pH, Zn2+ ion concentrations and partial hydrolysis by nuclease S1 was investigated. It was shown that about 90% of the RNA molecule is accessible to both dyes, when the ionic strength is near of 0.01 (pH 7). Approximately half of the RNA becomes inaccessible to dyes, when the ionic strength was increased up to 0.08-0.24 (pH 4.7-7), independent on the presence of Zn2+ ions (10(-3) M). About a half of the ds-, and a quarter of the ss-segments of the RNA, deduced from the secondary structure model were protected from the interaction with EtBr and AO. The hydrolysis of about a half of ss-segments upon addition of the Zn2+ (10(-3) M) ions did not affect the RNA tertiary structure. The experimental data obtained confirm the idea of the existence of some "nucleus" (or "nuclei") within the 16S rRNA molecule. The "nucleus" seems to be inaccessible to the dyes and is very stable to heat denaturation. It was supposed that this structure is organized by means of interaction of some of the parallelly oriented ds-segments, as it was suggested earlier for the phage MS2 RNA structure.     

Two-cistronic expression plasmids for high-level gene expression in Escherichia coli preventing translational initiation inhibition caused by the intramolecular local secondary structure of mRNA

Two-cistronic expression plasmids for the wild-type solubilized domain of porcine NADPH-cytochrome P450 reductase (PsCPR) gene in Escherichia coli were systematically constructed using a solubilized domain of porcine cytochrome b5 gene (Psb5 gene) or a derivative of it as the first cistron to examine their utility for second gene expression preventing the translational inhibition caused by the intramolecular local secondary structure of mRNA at the ribosome-binding site (RBS). The mRNAs from the plasmids lacking an RBS for the second cistron (SD2) accumulated very low levels of PsCPR, while those from the plasmids having an SD2 accumulated higher levels of PsCPR. The level of accumulation of PsCPR by the mRNA from plasmid pCbSD-T-CPR-3, which has an SD2 upstream of the termination codon of the first cistron, was higher than for those with an SD2 in the intercistronic region. The predicted intramolecular local secondary structures at the SD2 of mRNAs from these plasmids were stable enough to cause translational initiation inhibition. These results indicate that the use of a two-cistronic expression plasmid is an effective way to overcome translational initiation inhibition. Improved plasmids, pCP1 and pCP2P, were constructed from pCbSD-T-CPR-3. Using these plasmids, the solubilized donain of porcine NADH-cytochrome b5 reductase was also highly accumulated on prevention of the translational initiation inhibition. These plasmids are expected to be useful tools for the comprehensive high-level expression of heterologous genes in E. coli cells.     

Studies of virus structure by laser-Raman spectroscopy. II. MS2 phage, MS2 capsids and MS2 RNA in aqueous solutions.

Laser-Raman spectra of the bacteriophage MS2, and of its isolated coat-protein and RNA components, have been obtained as a function of temperature in both H₂O and D₂O (deuterium oxide) solutions. The prominent Raman lines in the spectra are assigned to the amino acid residues and polypeptide backbone of the viral coat protein and to the nucleotide residues and ribosyl-phosphate backbone of the viral RNA. The Raman frequencies and intensities, and their temperature dependence, indicate the following features of MS2 structure and stability. Coat-protein molecules in the native phage maintain a conformation determined largely by regions of β-sheet (~60%) and random-chain (~40%) structures. There are no disulfide bridges in the virion and all sulfhydryl groups are accessible to solvent molecules. Protein-protein interactions in the virion are stable up to 50 °C. Release of viral RNA from the virion does not affect either the conformation of the coat-protein molecules or the thermal stability of the capsid. MS2 RNA within the virion contains a highly ordered secondary structure in which most (~85%) of the bases are either paired or stacked or both paired and stacked and in which the RNA backbone assumes a geometry of the A-type. When RNA is partially or fully released from the virion its overall secondary structure at 32 °C is unchanged. However, the exposed RNA is more susceptible to changes in secondary structure promoted by increasing the temperature. Thus the viral capsid exerts a significant stabilizing effect on the secondary structure of MS2 RNA. This stabilization is ionic-strength dependent, being more pronounced in solutions containing high concentrations of KCl. Raman intensity profiles as a function of temperature reveal that disordering of the MS2 RNA backbone and rupture of hydrogen-bonding between complementary bases are gradual processes, the major portions of which occur above 40 °C. However, the unstacking of purine and pyrimidine bases is a more co-operative phenomenon occurring almost exclusively above 55 °C.     

The accessibility of phage MS2 RNA to structure specific nucleases in various conditions

The accessibility of ds-and ss-segments of phage MS2 RNA to ds-and ss-specific nucleases (RNase III, nuclease SV and nuclease S1) was studied. The results show that the RNA has hydrolysis sites for all the nucleases used. These sites are unvariable in a wide range of the conditions (ionic strength, pH, bivalent cations and temperature) and are not changed also after denaturation-renaturation of the RNA. This testifies that the distribution and interactions of ds-and ss-segments in the whole molecule are very specific and stable.     

Secondary structure of MS2 phage RNA and bias in code word usage.

Based on the secondary structural model of MS2 RNA, it is shown that, in base-pairing regions of the RNA, there is a bias in the use of synonymous codons which favours C and/or G over U and/or A in the third codon positions, and that in non-pairing regions, there is an opposite bias which favours U and/or A over C and/or G. This nature is interpreted as a result of selective constraint which stabilises the secondary structure of the single-stranded RNA genome of the MS2 phage.     

Translational stimulation by reovirus polypeptide sigma 3: substitution for VAI RNA and inhibition of phosphorylation of the alpha subunit of eukaryotic initiation factor 2.

COS cells transfected with plasmids that activate DAI depend on expression of virus-associated I (VAI) RNA to prevent the inhibitory effects of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) kinase (DAI) and restore the translation of vector-derived dihydrofolate reductase mRNA. This VAI RNA requirement could be completely replaced by reovirus polypeptide sigma 3, consistent with its double-stranded RNA (dsRNA)-binding activity. S4 gene transfection of 293 cells also partially restored adenovirus protein synthesis after infection with the VAI-negative dl331 mutant. In dl331-infected 293 cells, eIF-2 alpha was present mainly in the acidic, phosphorylated form, and trans complementation with polypeptide sigma 3 or VAI RNA decreased the proportion of eIF-2 alpha (P) from approximately 85 to approximately 30%. Activation of DAI by addition of dsRNA to extracts of S4 DNA-transfected COS cells required 10-fold-higher levels of dsRNA than extracts made from cells that were not producing polypeptide sigma 3. In extracts of reovirus-infected mouse L cells, the concentration of dsRNA needed to activate DAI was dependent on the viral serotype used for the infection. Although the proportion of eIF-2 alpha (P) was greater than that in uninfected cells, most of the factor remained in the unphosphorylated form, even at 16 h after infection, consistent with the partial inhibition of host protein synthesis observed with all three viral serotypes. The results indicate that reovirus polypeptide sigma 3 participates in the regulation of protein synthesis by modulating DAI and eIF-2 alpha phosphorylation.     

Translational regulation of the lysis gene in RNA bacteriophage fr requires a UUG initiation codon

Summary Single nucleotide substitutions identify a UUG triplet as the initiation codon of the lysis gene in RNA bacteriophage fr. This initiation codon is non-functional in de novo initiation but is activated by translational termination at the overlapping coat gene. The UUG initiation codon is crucial for gene regulation in the phage, as it excludes uncontrolled access of ribosomes to the start of the lysis gene. Replacement of UUG by either GUG or AUG results in the loss of genetic control of the lysis gene. A model is presented in which initiation factor IF3 proofreads de novo initiation at UUG codons.     

The regulatory region of MS2 phage RNA replicase cistron. IV. Functional activity of specific MS2 RNA fragments in formation of the 70 S initiation complex of protein biosynthesis.

The initiation region of the MS2 replicase cistron can be isolated as a fragment 59 bases in length protected from RNAase by the binding of the coat protein which serves as a translational repressor. This fragment MS2 R(-53 leads to 6) starts 53 bases before the initiation codon and retains full activity in binding ribosomes. We have investigated the functional activity in initiation of a series of fragments from this region variously shortened from the 5'-end. Ribosome protected fragments starting 17 or 21 bases before the AUG are unable to rebind to ribosomes. The shortest fragment which has this activity was produced by partial S1 nuclease digestion and starts 33 to 35 bases before the AUG. The initiation signal comprises some nucleotides between 21 and 33 bases before the initiation codon and the regulatory region responsible for initiation is longer than that protected by the ribosome in the final initiation complex.     

RNA secondary structure and translation inhibition: analysis of mutants in the rplJ leader

We have carried out measurements of the stable binding of the ribosomal protein (r-protein) complex L10-L7/L12 to mutant forms of the mRNA leader of the rplJ operon of Escherichia coli. One of the point mutations, base 1548, which lies within the L10-L7/L12-protected region, almost completely abolishes in vitro formation of a stable complex of L10-L7/L12 with rplJ mRNA leader, and a second point mutation, base 1634, strongly reduces it. These observations constitute strong support for the proposition that L10-L7/L12 binds to the rplJ leader in bringing about translational feedback. To account for the action of these and other mutations, and to explain the mechanism of translation feedback inhibition, we suggest a secondary structure model involving alternate forms of the rplJ mRNA leader.     

Studies on the bacteriophage MS2. 23. Fixation of the MS2 RNA acid structure by formaldehyde

When MS2 RNA is heated at low p^H in the presence of formaldehyde, a fast-sedimenting conformation is irreversibly formed. This species is homogeneous and stable at neutral p^H. Its formation further requires Mg⁺⁺ ions and low ionic strength. The most compact form sediments at 46S and is obtained after short reaction times at high temperature or after long reaction times at 35°C. Melting curves suggest that the specific acid conformation is not destabilized by the formaldehyde addition reaction. The p^H at which this acid conformation is formed depends on the MgC1₂ concentration. At 10^?2M MgCl₂ the midpoint is p^H 5.3. Removal of more than half of the bound formaldehyde has no effect on the compactness of the molecule, although most of the original secondary structure has not yet re-formed.