The regulatory region of phage fr replicase cistron. III. Initiation activity of specific fr RNA fragments.

RNA fragments from phage fr covering the complete or part of the replicase cistron initiation region have been used as templates in the formation of a ribosomal initiation complex in vitro. The results so obtained together with our earlier findings in a similar approach applied to fragments of the structurally related RNA from phage MS2 have allowed us to pinpoint the boundaries of the replicase cistron initiation region on phage RNA. A structural model of the above initiation region has been provided which shows that besides the minimal initiation region (comprises the Shine-Dalgarno sequence and initiator AUG), the flanking regions are also involved and are responsible for additional interactions with the ribosome. The flanking regions possibly contribute to the stability of specific contact between the ribosome and template realized by the minimal initiation region.     

Synthesis and functional activity of translation initiation regions in mRNA. 20-base polyribonucleotides from the replicase gene of phage MS2 and fr

Three 20-base polyribonucleotides, AAACAUGAGGAAUACCCAUG (I), AAACAUGAGGAAAACCCAUG (II), AAACAUGAAGAAUACCCAUG (III), corresponding to the minimal initiation region for the replicase gene of phage MS2 and fr or having some differences were synthesized using enzymatic methods. The template activity of the synthesized polynucleotides in initiation and their capacity to bind phage coat protein were studied under conditions optimal for native mRNA. Polynucleotides I and II exhibit template activity comparable to that of the native phage RNA fragments. Polynucleotide III with the destroyed SD sequence dit not manifest any functional activity either as template or in binding to MS2 phage coat protein.     

Primary structure of a fragment of cDNA from phage fr

The nucleotide sequence of a 1392 bp fragment of phage fr cDNA has been determined. The fragment contains 3'-terminal part of the A-protein gene, the complete coat protein gene, and beginning of the replicase gene. A comparison between the sequences of the corresponding genes and regulatory regions from the phage fr and MS2 genomes reveals 320 base changes.     

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.     

A comparison of two phage coat protein-RNA interactions.

The interaction between the coat protein of the group I bacteriophage fr with its translational operator site is compared with the previously studied R17 interaction. The sequence of the two RNA binding sites differ by 2 of 20 nucleotides and two coat proteins by 17 of 129 amino acids. An analysis of the binding of fr coat protein to 24 operator variants revealed that the two proteins recognize operator sequences in virtually the same way. However, fr coat protein binds to nearly every RNA 6 to 14-fold tighter than R17 coat protein. Since the fr operator is a weaker binding variant and the fr coat protein shows a different temperature dependence of binding, it is unlikely that the two systems have different Kas in vivo. RNA fragments containing the operator sequences can initiate the capsid assembly with both fr and R17 coat protein. Surprisingly, the two coat proteins can form a mixed capsid in vitro.     

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.     

Complete nucleotide sequence of the group I RNA bacteriophage fr

We report the complete nucleotide sequence of the group I RNA bacteriophage fr. The entire genome consists of 3575 nucleotides, six nucleotides more than the only other sequenced group I representative, MS2. The greatest divergence between these phages occurs in the 5' terminal region of the A gene, while the lysis-replicase gene overlap, the coat gene and the central region of the replicase gene are highly conserved. Overall sequence homology between fr and MS2 is 77%. Here, we present a general comparison between the two phages. In the accompanying paper we use phylogenetic sequence comparison between MS2 and fr to deduce the secondary structure at the 3' untranslated region.     

Cooperative binding of R17 coat protein to RNA.

The binding of the R17 coat protein to synthetic RNAs containing one or two coat protein binding sites was characterized by using nitrocellulose filter and gel-retention assays. RNAs with two available sites bound coat protein in a cooperative manner, resulting in a higher affinity and reduced sensitivity to pH, ionic strength, and temperature when compared with RNAs containing only a single site. The cooperativity can contribute up to -5 kcal/mol to the overall binding affinity with the greatest cooperativity found at low pH, high ionic strength, and high temperatures. Similar solution properties for the encapsidation of the related fr and f2 phage suggest that the cooperativity is due to favorable interactions between the two coat proteins bound to the RNA. This system therefore resembles an intermediate state of phage assembly. No cooperative binding was observed for RNAs containing a single site and a 5' or 3' extension of nonspecific sequence, indicating that R17 coat protein has a very low nonspecific binding affinity. Unexpectedly weak binding was observed for several RNAs due to the presence of alternative conformational states of the RNA.     

The binding site for coat protein on bacteriophage Qbeta RNA.

The site of interaction of phage Qbeta coat protein with Qbeta RNA was determined by ribonuclease T1 degradation of complexes of coat protein and [32P]-RNA obtained by codialysis of the components from urea into buffer solutions. The degraded complexes were recovered by filtration through nitrocellulose filters, and bound [32P]RNA fragments were extracted and separated by polyacrylamide gel electrophoresis. Fingerprinting and further sequence analysis established that the three main fragments obtained (chain lengths 88, 71 and 27 nucleotides) all consist of sequences extending from the intercistronic region to the beginning of the replicase cistron. These results suggest that in the replication of Qbeta, as in the case of R17, coat protein acts as a translational repressor by binding to the ribosomal initiation site of the replicase cistron.     

Hexamer of bacteriophage f2 coat protein as a repressor of bacteriophage RNA polymerase synthesis.

Formation of complex I between phage f2 RNA and coat protein, leading to repression of phage RNA polymerase synthesis, depends nonlinearly upon the concentration of the coat protein. Maximum formation of complex I was observed when six molecules of coat protein were bound to one molecule of RNA. RNase digestion of a glutaraldehyde-fixed complex left, as the products, coat protein oligomers. The heaviest, hexamers, predominated in the mixture. It was also shown that, in an ionic environment required for phage protein synthesis, coat protein at a concentration optimum for complex I formation exists in solution as a dimer. The results indicate that the translational repression of the RNA polymerase cistron is due to a cooperative attachment to phage template of three dimers of coat protein, forming a hexameric cluster on an RNA strand.     

The ratio of coat protein to bacteriophage f2 RNA in the translational repressor complex]

One of the mechanisms underlying the regulation of the bacteriophage f2 RNA translation is the repression of the phage RNA-replicase formation by coat protein. This repression is due to the formation of a complex between f2 RNA and coat protein (complex I). In this work the mechanism of complex I formation as well as the effect of this complex on the f2 RNA-replicase formation was followed by inhibition of alanine incorporation into RNA-replicase polypeptide which was separated by polyacrylamide gel electrophoresis. The molar ratios of protein to f2 RNA in complex I were analyzed by sucrose gradient sedimentation. It was been found that complex I consists of six molecules of coat protein bound per one molecule of RNA. Ribonuclease digestion of the glutaraldehyde-fixed complex resulted in a mixture of products in which the hexamers of coat protein molecules were predominant. This indicates that the six molecules of coat protein bound to f2 RNA are neighbouring. It has been also shown that under conditions required for phage protein synthesis, coat protein occurs in solution is dimer. The results show that the translational repression of the RNA-replicase cistron is due to the cooperative attachment of three dimers of coat protein to phage template, forming a hexameric cluster on the RNA strand. The proposed mechanism of the complex I formation seems to be in good agreement with the sequence of events in the phage F2 life cycle. It is known that shortly after infection of the host cell the coat protein and phage RNA-replicase begin to be synthesised. According to our findings, the first portions of coat protein do not affect the translation of the RNA-replicase gene since at low concentration the coat protein occure in the form of monomers. At a later period of phage development, when the concentration of coat protein is sufficiently high to promote the formation of protein dimers, the translational repressor complex is formed and the RNA-replicase gene becomes inoperative.     

Serological Relatedness of the Ribonucleic Acid-Containing Coliphages

The serological relationship of the ribonucleic acid (RNA)-containing coliphages MS-2, M-12, R-17, f₂, β, fr, f₄, and Qβ was determined. Antisera against MS-2, R-17, f₂, fr, and Qβ neutralized the infectivity of all of these RNA phages to varying degrees. Although each phage was serologically distinct, the antisera cross-reacted with certain phages to approximately the same degree, indicating the antigenic relationship of the coat proteins of these phages. Adsorption of anti-MS-2 sera with varying concentrations of all of the phages demonstrated that these viruses contain similar yet unique antigenic determinants. It is suggested that these RNA phages are mutants of two related phages rather than of the same phage.     

Location of the cistron of the tobacco mosaic virus coat protein.

Treatment of tobacco mosaic virus (TMV) RNA with T1 RNase under mild conditions cuts the RNA molecule into a large number of fragments, only a few of which may be specifically recognized by disks of TMV protein. It has been shown elsewhere that these specifically recognized RNA fragments are a part of the coat protein cistron, the portion coding for amino acids 95 to 129 of the coat protein. It is reported that different size classes of partially uncoated virus particles were prepared by limited reconstitution between TMV RNA and protein or by partial stripping of intact virus with DMSO. Both procedures produce nucleoprotein rods in which the 5'-terminal portion of the RNA is encapsidated and the 3'-terminal region is free. The free and the encapsidated portions of the RNA were each tested for the ability to give rise to the aforesaid specifically recognized fragments of the coat protein cistron upon partial T1 RNase digestion. It was found that only the 3'-terminal third of the virus particle need to be uncoated in order to expose the portion of the RNA molecule from which these fragments are derived. We conclude, therefore, that the coat protein cistron is situated upon the 3'-terminal third of the RNA chain, i.e. within 2000 nucleotides of the 3'-end.     

Effect of the sequences upstream from the ribosome-binding site on the yield of protein from the cloned gene for phage MS2 coat protein

The translational efficiency of the coat protein gene of phage MS2 has been examined in vivo with respect to neighbouring sequences. The cloned MS2 DNA has been gradually shortened starting at the 5' or 3' terminus, and its effect on coat protein synthesis monitored. Removal of the 3'-terminal sequences had little influence. In contrast, the gradual removal of the 5'-terminal region profoundly reduces translation. Long before the ribosomal binding site (RBS) of the coat protein (CP) gene is reached, the yield of CP has dropped by one order of magnitude. Functional half-lives of the various messengers were found not to be significantly different. Available evidence indicates that the secondary structure of the RBS in native and shortened MS2 RNA is identical. We infer that important determinants for ribosome recognition lie 5' to the RBS region of the MS2 RNA coat gene.     

Probing sequence-specific RNA recognition by the bacteriophage MS2 coat protein.

We present the results of in vitro binding studies aimed at defining the key recognition elements on the MS2 RNA translational operator (TR) essential for complex formation with coat protein. We have used chemically synthesized operators carrying modified functional groups at defined nucleotide positions, which are essential for recognition by the phage coat protein. These experiments have been complemented with modification-binding interference assays. The results confirm that the complexes which form between TR and RNA-free phage capsids, the X-ray structure of which has recently been reported at 3.0 A, are identical to those which form in solution between TR and a single coat protein dimer. There are also effects on operator affinity which cannot be explained simply by the alteration of direct RNA-protein contacts and may reflect changes in the conformational equilibrium of the unliganded operator. The results also provide support for the approach of using modified oligoribonucleotides to investigate the details of RNA-ligand interactions.     

Principles of selective inactivation of the virus genome. IV. The effect of UV-irradiation of phage MS2 on its binding with anti-MS2-immunoglobulins

Ultraviolet (254 nm) irradiation of the bacteriophage MS2 results in the decrease of the number of antigenic determinants exposed on the virion surface. The cross-section of the decrease, as measured by the number of anti-MS2 IgG molecules bound per virion, is 10(-16) mm2 per photon. The decrease of the phage-antibody binding proceeds after irradiation with a rate constant of about 5 x 10(-3) min-1. Since the antigenic determinants of the phage MS2 coat protein does not contain photoreactive amino acid residues, the irradiation-induced decrease of the phage antibody binding is determined, most probably, by the shielding of the antigenic determinants. Such shielding could be caused by rearrangement of coat protein molecules and/or of the capsid induced by photomodification of non-antigenic fragments of coat protein and/or of intraphage RNA.     

Ribosomal protein S1 in the complex of E. coli ribosomal subunit 30S with phage MS2 RNA interacts with internal region of the replicase gene

The MS2 RNA fragments bound to ribosomal protein S1 within the complex of MS2 RNA with 30S ribosomal subunit have been isolated using a specially developed procedure and sequenced by the base-specific enzymatic method. The S1-binding site on MS2 RNA was identified as UUUCUUACAUGACAAAUCCUUGUCAUG and mapped within the replicase gene at positions 2030-2056. This finding suggests that ribosome-MS2 RNA interaction involves at least two different regions of the phage RNA--the internal region of the replicase gene (S1-binding site) and ribosome-binding site of the coat protein gene. The possible spatial proximity between these two regions is discussed.     

Observations concerning the sequence of two additional specifically encapsidated RNA fragments originating from the tobacco-mosaic-virus coat-protein cistron.

The incubation of 25-S tobacco mosaic virus (TMV) protein with a mixture of RNA fragments produced by partial T1 RNase digestion of TMV RNA results in the encapsidation of only a few species of RNA. In addition to the most predominant species, fragment 1, whose sequence has been described in the prededing paper, two other species, fragment 41 and fragment 21 are coated by the protein. These two RNA fragments were purified by polyacrylamide gel electrophoresis and subjected to total digestion with pancreatic and T1 RNase. The oligonucleotides were separated by paper electrophoresis and characterized insofar as possible by digestion with the complementary ribonuclease. From the amino acid coding capacity of the oligonucleotides liberated from fragments 41 and 21 by T1 RNase digestion, it appears that these two fragments, like fragment 1, are derived from the coat protein cistron. They are situated immediately prior to fragment 1 and, together with this fragment, consitute a continuous stretch of 232 nucleotides of the cistron which codes for animo acids 53 to 130 of the coat protein. The order of the fragments in the sequence is 21-41-1. A possible model for the secondary structure of this portion of the sequence is proposed.     

RNA binding properties of the coat protein from bacteriophage GA.

The coat protein of bacteriophage GA, a group II RNA phage, binds to a small RNA hairpin corresponding to its replicase operator. Binding is specific, with a Ka of 71 microM -1. This interaction differs kinetically from the analogous coat protein-RNA hairpin interactions of other RNA phage and also deviates somewhat in its pH and salt dependence. Despite 46 of 129 amino acid differences between the GA and group I phage R17 coat proteins, the binding sites are fairly similar. The essential features of the GA coat protein binding site are a based-paired stem with an unpaired purine and a four nucleotide loop having an A at position -4 and a purine at -7. Unlike the group I phage proteins, the GA coat protein does not distinguish between two alternate positions for the unpaired purine and does not show high specificity for a pyrimidine at position -5 of the loop.