Translation of the RNAs of brome mosaic virus: The monocistronic nature of RNA1 and RNA2

Each of the two largest brome mosaic virus RNAs, RNA1 and RNA2, directs the synthesis of a large protein in cell-free extracts derived from wheat embryo. The size of each protein represents the translation of almost the entire length of the corresponding RNA. It was shown previously that brome mosaic virus RNA4 directs the synthesis of the coat protein and that brome mosaic virus RNA3, although it also contains the coat protein cistron, is translated mostly into a single product unrelated to the coat protein (Shih & Kaesberg, 1973). Thus, the brome mosaic virus genome encodes a total of four proteins.     

Cell-free translation of murine coronavirus RNA.

The coding assignments of the intracellular murine hepatitis virus-specific subgenomic RNA species and murine hepatitis virion RNA have been investigated by cell-free translation. The six murine hepatitis virus-specific subgenomic RNAs were partially purified by agarose gel electrophoresis and translated in an mRNA-dependent rabbit reticulocyte lysate, and the cell-free translation products were characterized by gel electrophoresis, immunoprecipitation, and tryptic peptide mapping. These studies have shown that RNA 7 codes for the nucleocapsid protein, RNA 6 codes for the E1 protein, RNA 3 codes for the E2 protein, and RNA 2 codes for a 35,000-dalton nonstructural protein. Genomic RNA directs the cell-free synthesis of three structurally related polypeptides of greater than 200,000 in molecular weight.     

Template activity of complexes formed between bacteriophage f2 RNA and coat protein.

Formation of complexes between f2 RNA polymerase cistron was partially inhibited, some RNA and coat protein was studied using salt conditions which are optimum for phage protein synthesis. In this ionic environment, coat protein precipitation can be prevented by sulfhydryl group-protecting agents. Complexes formed at different protein-RNA input molar ratios were isolated and tested for template activity in an in vitro protein synthesizing system. Simultaneously, the number of protein molecules bound per RNA strand in such complexes was measured by the membrane (Millipore) filtration technique. Under conditions in which translation of the RNA strands were complexed with six molecules of coat protein, whereas some remained unbound. Strong inhibition of the translation of the RNA polymerase cistron was observed when each of the RNA strands present in the mixture was associated with six molecules of coat protein.     

Coronavirus multiplication: locations of genes for virion proteins on the avian infectious bronchitis virus genome.

Six overlapping viral RNAs are synthesized in cells infected with the avian coronavirus infectious bronchitis virus (IBV). These RNAs contain a 3'-coterminal nested sequence set and were assumed to be viral mRNAs. The seven major IBV virion proteins are all produced by processing of three polypeptides of ca. 23, 51, and 115 kilodaltons. These are the core polypeptides of the small membrane proteins, the nucleocapsid protein, and the 155-kilodalton precursor to the large membrane proteins GP90 and GP84, respectively. To determine which mRNAs specify these polypeptides, we isolated RNA from infected cells and translated it in a messenger-dependent rabbit reticulocyte lysate. Proteins of 23, 51, and 110 kilodaltons were produced. Two-dimensional tryptic peptide mapping demonstrated that these proteins were closely related to the major virion proteins. Fractionation of the RNA before cell-free translation permitted the correlation of messenger activities for synthesis of the proteins with the presence of specific mRNAs. We found that the smallest RNA, RNA A, directs the synthesis of P51, the nucleocapsid protein. RNA C, which contains the sequences of RNA A, directs the synthesis of the small membrane protein P23. RNA E directs the synthesis of the large virion glycoproteins. These results supported a model in which only the unique 5'-terminal domain of each IBV mRNA is active in translation and enabled us to localize genes for virion proteins on the IBV genome.     

Polysomal Localization of R17 Bacteriophage-Specific Protein Synthesis

Synthesis of viral ribonucleic acid (RNA) polymerase, maturation protein, and coat protein in Escherichia coli infected with bacteriophage R17 occurs mainly on polysomes containing four or more ribosomes. The 30S ribosomal subunits through trimer-size polysomes, which are associated with all of the R17-specific proteins and are predominant in the infected cell, synthesize only coat protein. These structures may accumulate as products derived from larger polysomes as a result of failure in the release of nascent polypeptides after termination of chain growth. Appreciable amounts of viral coat protein remain attached to ribosomes and polysomes during R17 bacteriophage replication, supporting the hypothesis of the repressor role of this protein. The time course of synthesis of virus-specific proteins obtained from the polysomes of infected cells demonstrated regulated R17 messenger RNA translation consistent with the idea that coat protein is preferentially synthesized whereas the synthesis of noncoat proteins is suppressed.     

Regulation of RNA replication in RNA-containing bacteriphages. RNA synthesis in coat protein polar mutants]

The synthesis of RNA by polar coat protein mutants f2sus3 and Qbetaam12 under suppressor (Escherichia coli S26R1E, Su+-1; H12R8a Su+-3) and non-suppressor (E. coli AB259; S26) conditions was examined. It was demonstrated that the synthesis of viral RNA under non-suppressor conditions in the presence of rifamycin produced the same gaussian pattern of rates as the synthesis of RNA by wild type phage or non-polar coat protein mutants. However, the total amount of RNA was decreased approximately 10-fold and the peak of RNA synthesis was displaced 7--10 min later. The number of infective centers was reduced also 10-fold indicating that a certain time-lapse was required to overcome the polarity of the parental RNA, this process being of single occurrence, exclusively on the parental RNA, but not on the progeny strains. As a consequence, it was concluded that the initiation of translation at the replicase cistron starts on the nascent RNA chains within the replicative complexes and not on the fully-synthesized templates with their complete secondary structure. The data obtained are not in contradiction with the hypothesis concerning the role of the repressor complex II (replicase-RNA) to slow down the synthesis of replicase and RNA in the coat protein mutants. The polarity can not be responsible probably for the blocking of the replicase cistron on the nascent chain following the block of coat protein cistron. Therefore, it appears appropriate to assume the existence of two binding sites for the replicase as repressor which is in keeping with the conclusions of Weissmann and co-workers.     

Immunochemical analysis of the products of translation of mRNA hybridized with the left HindIII-A-Sa1-fragment of vaccinia virus DNA

The left HindIII-A-Sal fragment of the vaccinia virus DNA has been analyzed by the technique of mRNA hybridizational selection with the subsequent translation in cell-free protein-synthesizing system from the rabbit reticulocytes. The viral mRNA hybridizable with the fragment was shown to direct the synthesis of 12, 17, 27, 42, 70 kD polypeptides in the cell-free protein-synthesizing system. Each of 12 and 42 kD polypeptides was demonstrated to react specifically with antisera to structural p12 and p42 coat proteins. The structural coat proteins p12, p20, p42 of the vaccinia virus are concluded to be the products of the same viral gene.     

Mechanism of Genome Expression in a Single-stranded RNA Virus from the Cultivated Mushroom [Agaricus bisporus (Lange) Imbach]

The single-stranded RNA genome of a bacilliform virus from the common cultivated mushroom, Agaricus bisporus, was translated in an in vitro rabbit reticulocyte system. Optimal conditions for translation of mushroom bacilliform virus (MBV) RNA were 2.5 mM Mg²⁺, 70 mM K⁺, pH 7.2, and 60μg/ml RNA. Gel electrophoretic analysis showed that MBV RNA directs the synthesis of two major polypeptides of MW 77,000 and 37,000 and possibly several minor polypeptides (MW 21,000—28,000). An RNA polymerase activity could not be detected in purified virus preparations. The findings support the notion that the MBV genome functions directly as messenger for protein synthesis and further establishes the closer similarity between MBV and viruses of higher plants than mycoviruses.     

Studies on the bacteriophage MS2. XVI. The termination signal of the A protein cistron

The RNA of bacteriophage MS2 codes for three viral proteins: the coat protein, the A protein and the replicase. Upon infection of various amber suppressor strains of Escherichia coli, we found a fourth viral protein, the synthesis of which was specifically dependent on the presence of an amber suppressor gene. It is shown that this polypeptide is formed by reading through the natural termination signal of the A protein cistron. This cistron therefore terminates with the nonsense codon UAG. The observed prolongation accounts for the addition of some 30 amino acids. Unlike the normal A protein, the longer polypeptide is probably not incorporated into mature phage particles.     

Non-Continuous Translation of Coat Protein and Ribonucleic Acid Polymerase Cistrons in MS2 Bacteriophage Ribonucleic Acid

In an MS2 phage ribonucleic acid (RNA)-directed in vitro protein-synthesizing system, the coat protein cistron and the adjacent RNA polymerase cistron are translated non-continuously. The ribosomes which have completed the synthesis of coat protein dissociate from the MS2 RNA and do not read through the intercistronic gap. Translation of the adjacent RNA polymerase cistron requires ribosomes other than those translating the coat protein cistron.     

Regulatory region of fr phage replicase cistron. II. Isolation and structure of specific fr RNA fragments

A new set of short RNA templates has been prepared for functional studies in initiation of translation in vitro. Number of individual RNA fragments which contain complete or part of the initiatory region of phage fr replicase cistron were isolated from complex fr RNA--fr coat protein. Their primary structure were determined by using standard fingerprint technique and rapid gel sequencing. Secondary structure of several RNA fragments and their binding activity with phage fr and MS2 coat proteins has been also studied.     

Regulation of gene expression at the translational level. The rescue factor reverses thermosensitive protein synthesis in N4316, a conditionally-lethal mutant of Escherichia coli defective in translation

Extracts of the conditionally-lethal mutant Escherichia coli N4316 are defective in a newly described translation factor, the rescue protein. We have analyzed the in vitro translation products of this mutant by gel electrophoresis during normal and arrested synthesis at the permissive and non-permissive temperatures. Translation programmed with MS2 bacteriophage RNA at the non-permissive temperature results in highly reduced synthesis of the coat protein with no detectable levels of the maturation and replicase products. Thus the relative number of copies of proteins synthesized by the ribosomes is altered in this mutant. In addition, there is mistranslation of the coat gene which results in the overproduction of the phage encoded no. 7 protein. Aberrant synthesis is also reflected in the increased read-through of termination codons during synthesis directed by phage RNAs harbouring amber mutations in the coat cistron. The rescue protein, purified from the parental strain, is able to complement the thermosensitive defect and restore proper synthesis. Biochemical characterization of the defect in the absence of rescue shows no detectable deficiency in the extent of initiation complex formation in reactions inhibited with sparsomycin. Peptidyltransferase is fully active as judged by the kinetics of formylmethionine-puromycin formation. However, rescue does exert an effect at the level of termination. In addition, the thermolability of the mutant can be reversed by dissociating 70S ribosomes into 30S and 50S subunits. Based on these and other observations, we propose tht rescue mediates a novel function in the association/dissociation of ribosomal subunits which is essential to the accuracy and efficiency of translation.     

Tobacco mosaic virus RNA directs the synthesis of a coat protein peptide in a cell-free system from wheat

Tobacco mosaic virus (TMV) RNA stimulates amino acid incorporation into protein in cell-free extracts from wheat germ, rye embryo and Escherichia coli. The properties of the wheat germ system are examined and the nature of the viral RNA-induced products studied with the aid of a virus mutant carrying a threonine → methionine replacement in its coat protein. A peptide containing this methionine residue is present in tryptic digests of mutant RNA-directed cell-free products, and is absent from digests of wild type RNA-directed products. The undigested cell-free product contains a very large number of polypeptides with molecular weights from 10,000 to 140,000, but little or no synthesis of correct sized coat protein is observed.     

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.     

Pharmacological-based translational induction of transgene expression in mammalian cells

In the quest for the development of pharmacological switches that control gene expression, no system has been reported that regulates at the translational level. To permit small-molecule control of transgene translation, we have constructed a farnesyl transferase inhibitor-responsive translation initiation factor. This artificial protein is a three-component chimaera consisting of the ribosome recruitment core of the eIF4G1 eukaryotic translation initiation factor, the RNA-binding domain of the R17 bacteriophage coat protein and the plasma membrane localization CAAX motif of farnesylated H-Ras. This membrane-delocalized translation factor is inactive unless liberated in the cytosol. Farnesyl transferase inhibitor FTI-277 prevents the membrane association of the CAAX motif and thus increases the cytoplasmic levels of the eIF4G fusion protein, which is then capable of inducing translation of the second cistron of a bicistronic messenger RNA containing an R17-binding site in its intercistronic space. Such direct translational control by farnesyl transferase inhibitors provides a system for fast, graded and reversible regulation of transgene expression.     

Incomplete polypeptides are formed in vitro by premature chain termination

The mechanism of incomplete polypeptides formation during protein synthesis was studied in the wheat germ cell-free system programmed with brome mosaic virus RNA 4. The synthesis of coat protein, the complete product of RNA 4 translation, was accompanied by the appearance of polypeptides of lower molecular mass. It was shown that incomplete products are formed by translation of different lengths of RNA 4, always from the first 5' AUG codon, and were due neither to proteolysis of coat protein nor to the translation of nucleolytic fragments of mRNA. The molecular masses of incomplete products were determined and the nucleotide sequence of RNA 4 was examined in the regions where wheat germ ribosomes stop translating. It was found that they contained, on average, a slightly higher guanosine content than the total coding part of RNA 4. Translation of RNA 4 in the reticulocyte lysate resulted in a marked diminution of incomplete polypeptides. Addition of high-speed supernatant from reticulocyte lysate prevented the formation of incomplete products during translation of RNA 4 in the wheat germ system. This suggests that reticulocyte lysate contains some factor(s) which facilitate the movement of ribosomes beyond the regions where the elongation is retarded.     

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.     

Mechanism of translational coupling between coat protein and replicase genes of RNA bacteriophage MS2.

We have analyzed the molecular mechanism that makes translation of the MS2 replicase cistron dependent on the translation of the upstream coat cistron. Deletion mapping on cloned cDNA of the phage shows that the ribosomal binding site of the replicase cistron is masked by a long distance basepairing to an internal coat cistron region. Removal of the internal coat cistron region leads to uncoupled replicase synthesis. Our results confirm the model as originally proposed by Min Jou et al. (1). Activation of the replicase start is sensitive to the frequency of upstream translation, but never reaches the level of uncoupled replicase synthesis.