The action of mutagens on MS2 phage and on its infective RNA. V. Kinetics of the chemical and functional changes of the genome under hydroxylamine treatment

The kinetics of chemical and functional changes induced in the genome of bacteriophage MS2 by hydroxylamine under the conditions of predominant modification of either cytidine (pH 5.0) or uridine (pH 8.0) have been studied.Comparison of the kinetics of chemical modifications of monomeric nucleotides with those of bacteriophage inactivation at pH 8.0 and 5.0 made it possible to estimate the effective number of exposed cytidine and uridine residues in the intra-phage RNA (B_eff^c and B_eff^u). The B_eff^u was close to that expected and increased from 70 to 130 as the temperature rose from 0 to 30°. The B_eff^c was much greater than that expected on the basis of the results with the monomer, suggesting that side reactions are involved in the inactivation of the phage at pH 5.0.A significant increase of the frequency of mutation occurs only under the conditions of predominant modification of cytidine (pH 5.0) at 0°. No such effect was observed at 30°. This was probably due to the increased contribution of inactivating side reactions. The effect of hydroxylamine on the phage under the conditions of predominant uridine modification (pH 8.0) did not lead to an increase in frequency of mutants.Incubation of the intact phage in acetate buffer resulted in considerable inactivation and mutations. Inactivation was inhibited by magnesium ions. Incubation at pH 5.5, of the phage inactivated by hydroxylamine treatment at pH 8.0, resulted in a considerable increase of the inefectivity with no effect on the frequency of mutants. The infectivity and the mutation frequency of the phage treated with hydroxylamine at pH 5.0 did not change as a result of incubation at pH 4.0 after the removal of the reagent.     

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.     

Principles of selective inactivation of a viral genome. Comparative kinetic study of modification of the viral RNA and model protein with oligoaziridines

Comparative kinetic analysis of inactivation of bacteriophage MS2 infectivity and aminoalkylation of a model protein (trypsin inhibitor) with oligoaziridines was performed in order to evaluate the selectivity of viral RNA modification with oligocationic reagents. The transition from ethyleneimine monomer to di-, tri-, and tetramer leads to a sharp increase in the rate constant of infectivity inactivation, whereas the rate constant of protein modification changes insignificantly. The selectivity coefficient of the phage RNA aminoalkylation relative to trypsin inhibitor modification increases in this series by more than an order of magnitude. This effect is probably associated with the strengthening of the reagent binding to the nucleic acid, which implies a reaction mechanism that involves the formation of a reactive intermediate. The latter might be an electrostatic complex of the oligocationic reagent and RNA, the only polyanion in the virion. A pronounced decrease in the rate constant of infectivity inactivation in the presence of multiply charged anions (in phosphate buffer) and a biogenic polyamine (spermine) favors this hypothesis. Increasing the reaction temperature increases the rate constant of infectivity inactivation and decreases selectivity of the viral RNA modification.     

Photodynamic activity of dyes with different DNA binding properties II. T4 phage inactivation.

The photosensitizing efficiency of six dyes--proflavine, 9-aminoacridine, ethidium bromide, thiopyronine, pyronine and acridine red--have been compared on the basis of the inactivation of sensitized T4 phage caused by light irradiation. This reaction was only measurable after diffusion of the dye through the phage capsid and was not observed in the presence of either chloroquine or quinacrine; it followed a single-hit kinetics as a function of the irradiation time. With each dye, a double reciprocal plot of the inactivation constant versus the dye concentration present gave rise to a linear relationship. From this relation, parameters were deduced which expressed the relative photosensitizing efficiencies. Dye-binding to the phages was measured and the proflavine-mediated inactivation appeared to be related to the amount of strongly bound molecules. Such a conclusion could not be reached in the case of 9-aminoacridine and ethidium bromide, which were much less efficient photosensitizers than proflavine, but which were also strongly bound to the phages. Thiopyronine was weakly bound to the phages; it had, however, the highest photosensitizing activity observed. These results indicate that various mechanisms are involved when the phage photosensitization is due to one dye or another.     

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.     

The regulatory region of MS2 phage RNA replicase cistron. Functional activity of individual MS2 RNA fragments

The present work deals with the structural-functional organization of regulatory regions of messenger RNAs. Some principles of the action of a translational repressor (coat protein) and the formation of the ribosomal initiation complex at the replicase cistron have been studied with MS2 phage RNA. When the complex of MS2 RNA with the coat protein is treated with T₁ ribonuclease, the coat protein selectively protects mainly two fragments (59 and 103 nucleotides in length) from digestion; these fragments contain the intercistronic regulatory region and the beginning of the MS2 replicase cistron. These polynucleotides have been isolated in a pure state and their primary structure has been established.It has been established that both MS2 RNA fragments contain all the necessary information for specific interaction with MS2 coat protein and form a complex with it with an efficiency close to that observed in the case of native MS2 RNA. They also provide the normal polypeptide chain initiation at the replicase cistron. Enzymatic binding of the second aminoacyl-tRNA and electrophoretic analysis of N-terminal dipeptides prove that only the true initiator codon of the replicase cistron is recognized by a ribosome despite the presence of a few additional AUG triplets within the polynucleotides. Under conditions of limited hydrolysis by T₁ ribonuclease, the beginning of the replicase cistron has been removed from the shortest polynucleotide leading to a complete loss of its ability to bind both the coat protein and a ribosome.Some principles of the functioning of the regulatory region in MS2 RNA as well as the nature of the initiator signal of protein biosynthesis are discussed.     

The binding of T4 gene 32 protein to MS2 virus RNA and transfer RNA.

Fluorescence titrations, absorption spectroscopy and stopped-flow techniques were used to study the interaction of T4 coded 32-protein (P 32) with MS2 RNA and total tRNA from E. coli under different ionic conditions. It is shown that the amount of MS2 RNA and tRNA secondary structure melted by P 32 varies markedly and reversibly within a range of ionic conditions under which the binding constant of P 32 to single-stranded nucleic acids unable to form stable hairpins remains higher than 10(8) M-1. Kinetic experiments suggest that P 32 dissociates from the MS2 RNA rewinding strand with a similar rate constant as calculated for the dissociation from single-stranded regions. Possible in vivo consequences of these findings are discussed.     

The RNA binding site of bacteriophage MS2 coat protein.

The coat protein of the RNA bacteriophage MS2 binds a specific stem-loop structure in viral RNA to accomplish encapsidation of the genome and translational repression of replicase synthesis. In order to identify the structural components of coat protein required for its RNA binding function, a series of repressor-defective mutants has been isolated. To ensure that the repressor defects were due to substitution of binding site residues, the mutant coat proteins were screened for retention of the ability to form virus-like particles. Since virus assembly presumably requires native structure, this approach eliminated mutants whose repressor defects were secondary consequences of protein folding or stability defects. Each of the variant coat proteins was purified and its ability to bind operator RNA in vitro was measured. DNA sequence analysis identified the nucleotide and amino acid substitutions responsible for reduced RNA binding affinity. Localization of the substituted sites in the three-dimensional structure of coat protein reveals that amino acid residues on three adjacent strands of the coat protein beta-sheet are required for translational repression and RNA binding. The sidechains of the affected residues form a contiguous patch on the interior surface of the viral coat.     

Molecular biological study of the vaccinia virus genome. IV. The late nonstructural 36K protein of vaccinia virus is vitally important

Two genetics markers: the herpes simplex virus thymidine kinase and Escherichia coli beta-galactosidase genes were inserted into the 36K protein gene of vaccinia virus located in a HindIII-P DNA fragment. An unstability of recombinant viruses with Lac(+)-phenotype were discovered. A mechanism of viruses unstable variants formation was proposed, it was confirmed by the results of hybridisation analyses of virus recombinant genomes. The importance of a late nonstructural 36K protein gene for virus reproduction was demonstrated.