Alterations in the Distribution of Labeled Ribonucleic Acid in Polyribosomes from Escherichia coli Infected with Bacteriophage R17

The distribution of labeled ribonucleic acid (RNA) associated with polysomes from Escherichia coli infected with the bacteriophage R17 was investigated. Pulse-labeling of RNA for 15 sec with (3)H-uridine resulted in increased labeling of the RNA associated with larger polysomes from infected cells as compared to control cells. Analysis of the RNA indicated that the increased labeling of large polysomes resulted from the presence of labeled double-stranded viral RNA. Other species of 15-sec pulse-labeled RNA entered into polysome formation in both infected and control cells. On the other hand, pulse-labeling of cultures for 15 sec with (3)H-uridine followed by a 5-min chase with unlabeled uridine resulted in a greater decrease in the amount of labeled RNA associated with large polysomes from infected cells as compared to control cells. This decreased labeling of large polysomes from infected cells was accompanied by an increased amount of label associated with the monomer to trimer regions. Analysis of RNA labeled under pulse-chase conditions indicated that virus infection resulted in an increased amount of heterogeneous 5 to 15S RNA in both the monomer to trimer and ribosomal subunit-soluble regions of the polysome profile. Labeled 5 to 15S RNA extracted directly from infected cells under pulse-chase conditions, without prior polysome fractionation, was characterized by a shift toward a distribution of smaller polynucleotides.     

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.     

Complementary transcribed T4 RNA. Association with the polysomes.

Pulse labelled bacteriophage T₄ RNA isolated from polysomes from either early or late infected cells were found to contain complementary RNA. The fraction of complementary late RNA was higher in the heaviest late polysomes. The RNA not associated with polysomes appeared to contain insignificant amounts of complementary RNA. The significance of these findings are discussed.     

Identification of Saint Louis encephalitis virus mRNA.

Saint Louis encephalitis (SLE) virus-specific RNA was recovered from infected HeLa cells by sodium dodecyl sulfate (SDS)-phenol-chloroform extraction, and the molecular species were resolved by SDS-sucrose gradient centrifugation and agarose gel electrophoresis. Sucrose gradient centrifugation revealed the presence of a 45S species, minor 20 to 30S heterogeneous species, and an 8 to 10 S RNA species in the cytoplasmic extract. Analysis of the same samples by electrophoresis on agarose gels, under both nondenaturing and denaturing conditions, revealed only two virus-specific RNA molecules, the 45S genome-sized RNA and an 8 to 10S species. Varying the gel concentration to facilitate analysis of nucleic acids with molecular weights ranging from 25,000 to 25 X 10(6) failed to reveal additional RNA species, although low levels of a putative double-stranded replicative form could conceivably have escaped detection. From our observations it appears that the heterogeneous RNA species and presumably the 20S RNase-resistant species reported in other investigations of flavivirus RNA are degradation products or conformers of the 45S molecule. Polysomes from SLE virus-infected cells were prepared and separated from contaminating nucleocapsid by centrifugation on discontinuous sucrose gradients. RNA extracted from these polysome preparations was analyzed by sucrose gradient centrifugation and agarose gel electrophoresis. The 45S SLE virus genome-size molecule was found to be the only RNA species associated with the polysomes. This molecule was sensitive to RNase digestion and was released from polysomes by EDTA and puromycin treatment. These findings provide direct evidence that the 45 S SLE virus RNA serves as the messenger during virus replication, in contrast to the 26S RNA species which functions as the predominant messenger during alphavirus replication.     

Defective Interfering Passages of Sindbis Virus: Nature of the Intracellular Defective Viral RNA

BHK cells infected with defective-interfering passages of Sindbis virus accumulate a species of RNA (20S) that is about half the molecular weight of the major viral mRNA (26S). We have performed competitive hybridization experiments with these species of RNA and have established that 20S RNA contains approximately 50% of the nucleotide sequences present in 26S RNA. Our further studies, however, demonstrate that 20S RNA is unable to carry out the messenger function of 26S RNA. We found very little of the defective RNA associated with polysomes in vivo. In addition, it was unable to stimulate protein synthesis in vitro under conditions in which 26S RNA was translated. We have also examined viral RNA synthesis in BHK cells infected with standard or defective-interfering passages of Sindbis virus. This comparison suggests that defective partioles do not synthesize a functional replicase.     

A Messenger RNA for Tobacco Mosaic Virus Coat Protein in Infected Tobacco Mesophyll Protoplasts

The low molecular weight tobacco mosaic virus (TMV)-specific RNA component (LMC) was demonstrated in tobacco mesophyll protoplasts by polyacrylamide gel electrophoresis of ¹⁴C-uridine-labelled RNA from infected protoplasts. Free and membrane-bound polysomes were isolated from infected protoplasts, and RNA extracted from them was analyzed. TMV-specific RNA species including full-length viral RNA, its replicative intermediate, and LMC were found in both free and membrane-bound polysomes, but were present in free polysomes in much larger amounts. In particular, as much as 37 % of total LMC in protoplasts was found in free polysomes. Fractionation of polysomes by sedimentation in sucrose gradients showed that LMC is associated with small-sized polysomes (mono- to tetrasomes). Polysomes of this size class produced viral coat protein in a cell-free protein synthesizing system from rabbit reticulocytes. On the other hand, full-length TMV-RNA was associated predominantly with larger polysomes which produced in the cell-free system TMV-specific high molecular weight polypeptides but no coat protein. These results indicated that LMC, a subgenomic RNA of TMV, in fact functions in vivo as messenger RNA for viral coat protein, as has been postulated on the basis of in vitro studies.     

Translational control of protein synthesis after infection by vesicular stomatitis virus.

Four hours after infection of BHK cells by vesicular stomatitis virus (VSV), the rate of total protein synthesis was about 65% that of uninfected cells and synthesis of the 12 to 15 predominant cellular polypeptides was reduced to a level about 25% that of control cells. As determined by in vitro translation of isolated RNA and both one- and two-dimensional gel analyses of the products, all predominant cellular mRNA's remained intact and translatable after infection. The total amount of translatable mRNA per cell increased about threefold after infection; this additional mRNA directed synthesis of the five VSV structural proteins. To determine the subcellular localization of cellular and viral mRNA before and after infection, RNA from various sizes of polysomes and nonpolysomal ribonucleoproteins (RNPs) was isolated from infected and noninfected cells and translated in vitro. Over 80% of most predominant species of cellular mRNA was bound to polysomes in control cells, and over 60% was bound in infected cells. Only 2 of the 12 predominant species of translatable cellular mRNA's were localized to the RNP fraction, both in infected and in uninfected cells. The average size of polysomes translating individual cellular mRNA's was reduced about two- to threefold after infection. For example, in uninfected cells, actin (molecular weight 42,000) mRNA was found predominantly on polysomes with 12 ribosomes; after infection it was found on polysomes with five ribosomes, the same size of polysomes that were translating VSV N (molecular weight 52,000) and M (molecular weight 35,000) mRNA. We conclude that the inhibition of cellular protein synthesis after VSV infection is due, in large measure, to competition for ribosomes by a large excess of viral mRNA. The efficiency of initiation of translation on cellular and viral mRNA's is about the same in infected cells; cellular ribosomes are simply distributed among more mRNA's than are present in growing cells. About 20 to 30% of each of the predominant cellular and viral mRNA's were present in RNP particles in infected cells and were presumably inactive in protein synthesis. There was no preferential sequestration of cellular or viral mRNA's in RNPs after infection.     

Action of ribonuclease upon the polysomes of cultured mouse cells

Summary Pancreatic ribonuclease (RNase) and³H-uridine were used to study certain compositional and ontogenetic features of the polysomes of strain L mouse cells. Growing cells were exposed to the radioactive nucleoside,³H-uridine, for brief defined periods, and the sensitivity of the polysomes to digestion by RNase was determined. The RNase-resistant RNA of polysomes is shown to be primarily ribosomal, and the RNase-sensitive material formed during brief pulse labeling studies is largely messenger RNA. Actinomycin D inhibition of RNA synthesis was used to confirm this identification. The technique described here was used to investigate the effects of hydrocortisone on polysome formation. The hormone (10⁻⁶ m) lessens the extent of the nucleoside incorporation into polysomal and total RNA and delays the appearance of newly synthesized 18 S and 28 S rRNA into cytoplasmic polysomes. This work was partially supported by grants from the United States Public Health Service (GM 10866), from the National Science Foundation (GB 13924), and from The University of Kansas General Research Fund.     

Large-sized polysomes in Chironomus tentans salivary glands and their relation to Balbiani ring 75S RNA

Polysomes from the salivary glands of Chironomus tentans were investigated to determine whether Balbiani ring 75S RNA is incorporated into polysomal structures, and thus probably acts as messenger RNA. A new extraction technique for obtaining ribonucleoproteins was applied that gives a high yield of polysomes with only moderate degradation of the cytoplasmic, high molecular weight RNA. The polysomes sedimented in a broad region (200-2,000S) with a peak value of about 700S, which suggested that they were partly of very large sizes. This was confirmed by visualization of the polysomes in the electron microscope: 400S polysomes contained mainly 11-16 ribosomes, and 1,500S polysomes about 60 ribosomes per polysome. However, polysomes containing 100 or more ribosomes were also observed. It was further established that most of the cytoplasmic 75S RNA was located in polysomes, preferentially in the most rapidly sedimenting ones. From the available information on Balbiani ring RNA in cytoplasm and the present demonstration of 75S RNA molecules in polysomes, it was concluded that at least some Balbiani ring RNA, generated as 75S RNA within the Balbiani rings, eventually enters polysomes without being measurably changed in size. The present information on the potential amino acid coding sequences in 75S RNA is discussed in relation to the large size of the polysomes observed.     

mRNA from the transforming segment of the adenovirus 2 genome in productively infected and transformed cells.

We have identified two mRNA species transcribed from the adenovirus 2 genome section (HindIII-G fragment) believed to harbor genes for initiation and maintenance of cell transformation. The HindIII-G fragment occupies the left 7.5% of the genome and is transcribed from left to right [poly(U:G) r strand]. Poly(A)-terminated labeled mRNA was isolated from polyribosomes of adenovirus 2 early infected KB cells and from the transformed cell line 8617, hybridization purified using the HindIII-G fragment, and electrophoresed on formamide-polyacrylamide gels. Viral mRNA's of 24S (1.2 X 10(6) daltons) and 14S (4.5 X 10(5) daltons) were isolated from early infected cells and of 22S (1.0 X 10(6) daltons) and 14S from 8617 cells. Hybridization competition indicated that HindIII-G-specific mRNA was present in the polysomes at one-sixth the concentration late after infection as compared with early, indicating that the proteins coded by the transforming segment may be synthesized at reduced amounts during late stages. Only 1/10 the amount of RNA labeled late annealed to the G fragment as compared with that labeled early (per weight of RNA). Thus, synthesis of transforming gene mRNA is probably "turned off" late after infection. Both 24S (22S) and 14S mRNA's from infected and 8617 cells were complementary to the Hpa I-E fragment (left 4.1% of genome). The Hpa I-E fragment is too small to encode 24S and 14S species, which implies that the 5'-terminal regions of both species are coded by the same DNA sequences.     

Translation and identification of the viral mRNA species isolated from subcellular fractions of vesicular stomatitis virus-infected cells.

The cytoplasm of vesicular stomatitis virus (VSV)-infected BHK cells has been separated into a fraction containing the membrane-bound polysomes and the remaining supernatant fraction. Total poly(A)-containing RNA was isolated from each fraction and purified. A 17S class of VSV mRNA was found associated almost exclusively with the membrane-bound polysomes, whereas 14,5S and 12S RNAs were found mostly in the postmembrane cytoplasmic supernatant. Poly(A)-containing VSV RNA synthesized in vitro by purified virus was resolved into the same size classes. The individual RNA fractions isolated from VSV-infected cells or synthesized in vitro were translated in cell-free extracts of wheat germ, and their polypeptide products were compared by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. The corresponding in vivo and in vitro RNA fractions qualitatively direct the synthesis of the same viral polypeptides and therefore appear to contain the same mRNA species. By tryptic peptide analysis of their translation products, the in vivo VSV mRNA species have been identified. The 17S RNA, which is compartmentalized on membrane-bound polysomes, codes for a protein of molecular weight 63,000 (P-63) which is most probably a nonglycosylated form of the viral glycoprotein, G. Of the viral RNA species present in the remaining cytoplasmic supernatant, the 14.5S RNA codes almost exclusively for the N protein, whereas the 12S RNA codes predominantly for both the NS and M proteins of the virion.     

Newly Synthesized mRNA Is Translated during the Initial Imbibition Phase of Germinating Maize Embryo

RNA synthesis is activated in the cells of the plant embryo very soon after the start of seed imbibition. We previously reported that mainly heterogeneous nuclear RNA is synthesized in the radicle of Zea mays embryo during the first hours of germination. The present study was undertaken in order to detect the time of appearance of the newly synthesized messenger RNA in the polysomes of germinating maize axes.

Free polysomes were prepared from embryonic axes rehydrated for 2 hours in the presence of radioactively labeled uridine. These polysomes were shown to be labeled and to contain labeled particles sedimenting, after dissociation with EDTA, in the 10S to 40S region of a sucrose gradient. The labeled polysomal RNA migrates heterogeneously in a gel with a mean size corresponding to about 16S, and 60% of these molecules are polyadenylated.

The data indicate that the newly synthesized RNA associated with the polysomes after 2 h of germination consists of messenger RNA molecules. Analysis of the polysomes prepared 0.5 and 1 h after the start of imbibition suggests that translation of the newly synthesized messenger RNA probably occurs within the 1st hour of imbibition of the isolated axis, thus well before the completion of the initial water uptake.

     

TRANSPORT OF VIRAL RNA IN KB CELLS INFECTED WITH ADENOVIRUS TYPE 2

Messenger RNA transport was studied in KB cells infected with the nuclear DNA virus adenovirus type 2. Addition of 0.04 µg/ml of actinomycin completes the inhibition of ribosome synthesis normally observed late after infection and apparently does not alter the pattern of viral RNA synthesis: Hybridization-inhibition experiments indicate that similar viral RNA sequences are transcribed in cells treated or untreated with actinomycin. The polysomal RNA synthesized during a 2 hr labeling period in the presence of actinomycin is at least 60% viral specific. Viral messenger RNA transport can occur in the absence of ribosome synthesis. When uridine-³H is added to a late-infected culture pretreated with actinomycin, viral RNA appears in the cytoplasm at 10 min, but the polysomes do not receive viral RNA-³H until 30 min have elapsed. Only 25% of the cytoplasmic viral RNA is in polyribosomes even when infected cells have been labeled for 150 min. The nonpolysomal viral RNA in cytoplasmic extracts sediments as a broad distribution from 10S to 80S and does not include a peak cosedimenting with 45S ribosome subunits. The newly formed messenger RNA that is ribosome associated is not equally distributed among the ribosomes; by comparison to polyribosomes, 74S ribosomes are deficient at least fivefold in receipt of new messenger RNA molecules.     

Coronavirus JHM: Cell-Free Synthesis of Structural Protein p60

Sac(-) cells infected with murine coronavirus strain JHM shut off host cell protein synthesis and synthesized polypeptides with molecular weights of 150,000, 60,000, and 23,000. The 60,000- and 23,000-molecular-weight polypeptides comigrated with virion structural proteins p60 and p23, and the 60,000-molecular-weight protein was identified as p60 by tryptic peptide fingerprinting. Polyadenylate-containing RNA [poly(A) RNA] extracted from the cytoplasm of infected cells directed the synthesis of both 60,000- and 23,000-molecular-weight polypeptides in messenger-dependent cell-free systems derived from mouse L-cells and rabbit reticulocytes. The reticulocyte system also synthesized a 120,000-molecular-weight polypeptide that was specifically immunoprecipitated by antiserum raised against JHM virions. The identity of the 60,000- and 23,000-molecular-weight in vitro products was established by comigration with virion proteins, immunoprecipitation, and in the case of p60, tryptic peptide fingerprinting. The cytoplasmic poly(A) RNAs which encoded p60 and p23 sedimented in sucroseformamide gradients at 17S and 19S, respectively, and were clearly separable. These RNAs were among the major poly(A) RNA species synthesized in the cytoplasm of actinomycin D-treated cells late in infection, and the in vitro translation of size-fractionated RNA released from polysomes confirmed that they represent physiological mRNA's. These results suggest that the expression of the coronavirus JHM genome involves more than one subgenomic mRNA.     

S6 phosphorylation accompanies recruitment of ribosomes and mRNA into polysomes in response to dichlororibofuranosyl benzimidazole

Dichlororibofuranosyl benzimidazole (DRB), a potent inhibitor of nuclear RNA synthesis and messenger RNA (mRNA) accumulation, produces a paradoxical mobilization of rRNA and mRNA from the subpolysomal pool into polysomes in HeLa cells during the first 40 min of treatment. S6 is phosphorylated concurrently with polysome accumulation, and ribosomal subunits containing phosphorylated S6 are preferentially localized in polysomes, indicating that they form initiation complexes more readily than their non-phosphorylated counterparts.     

Two 5S genes are expressed in chicken somatic cells.

Two 5S RNA species were detected in chicken cells. 5S I RNA has the nucleotide sequence of chicken 5S RNA previously published by Brownlee et al. (1) and 5S II RNA differs from it by 10 mutations. The secondary structure of both species is compatible with that proposed for other eukaryotic 5S RNAs. 5S II RNA represents 50-60% of 5S I RNA. Both species were found in total chicken liver and brain and were present in polysomes in the same relative proportions. Only one 5S RNA species could be detected in rat liver and HeLa cells. Chicken is the first vertebrate described so far in which two 5S RNA genes are expressed in somatic cells.     

Characterization of polysome-associated RNA from influenza virus-infected cells.

Virus-specific polysome-associated RNA (psRNA) and RNA after dissociation of polysomes were analyzed by direct hybridization with unlabeled viral RNA (vRNA) and complementary RNA (cRNA). psRNA after a 30-min pulse with [3H]uridine contained 28% labeled cRNA, 70% host RNA, and no vRNA. After dissociation, psRNA sedimented heterogeneously. Heavy RNA (greater than 60S), ribosomal subunit RNA (rsuRNA, 30-60S), free mRNA (fmRNA, 10-30S), and light RNA (less than 10S) contained 16%, 54%, 70% and 28% cRNA, respectively, but no vRNA. When actinomycin D (AcD) was added at 2 h postinfection, the nature of the psRNA depended on the concentration of AcD and the condition of the labeling. At AcD concentrations of 1 mug or more per ml, no detectable vRNA or cRNA was associated with polysomes. At 0.2 mug of AcD per ml (a concentration that partially inhibited cRNA synthesis) and 2 h of labeling at 2.5 h postinfection, psRNA contained 40% viral-specific RNA, which included both vRNA and cRNA in almost equal amounts. When polysomes were dissociated, however, viral-specific fm RNA from AcD-treated cells contained exclusively cRNA and no detectable vRNA. Increasing amounts of labeled vRNA were present in the heavy region of the gradient (and in the pellet), which also contained varying amounts of cRNA. The labeled vRNA appears to be associated with polysomes in a cesium chloride density gradient (rho = 1.525 g/ml). Although we have ruled out the trivial explanation of viral ribonucleoprotein contamination,the nature of the complex containing both polysomes and vRNA is unknown.     

Protein synthesis in extracts from interferon-treated Mengo virus infected cells

We previously showed in intact L cells that interferon treatment did not modify the shut-off of cellular RNA and protein synthesis induced by infection with Mengo virus although viral replication is inhibited (1,2). We have also demonstrated that inhibition of host protein synthesis was not due to degradation of messengers since cellular mRNA could be extracted from interferon-treated infected cells and efficiently translated in a reticulocyte lysate(2). Cellular mRNA was not degraded although 2–5A was present as reported here. We prepared cell-free systems from such cells at a time when cellular shut-off was fully established. The undegraded messengers remained untranslated under cell-free protein synthesis conditions and almost no polysomes were detected. The decreased amount of [³⁵S]Met-tRNA-40S complex observed in these lysates might account for the inhibition of protein synthesis at the level of initiation.     

Studies on the mechanism for entry of vesicular stomatitis virus glycoprotein g mRNA into membrane-bound polyribosome complexes

Glycoprotein mRNA (G mRNA) of vesicular stomatitis virus is synthesized in the cytosol fraction of infected HeLa cells. Shortly after synthesis, this mRNA associates with 40S ribosomal subunits and subsequently forms 80S monosomes in the cytosol fraction. The bulk of labeled G mRNA is then found in polysomes associated with the membrane, without first appearing in the subunit or monomer pool of the membrane-bound fraction. Inhibition of the initiation of protein synthesis by pactamycin or muconomycin A blocks entry of newly synthesized G m RNA into membrane-bound polysomes. Under these circumstances, labeled G mRNA accumulates into the cytosol. Inhibition of the elongation of protein synthesis by cucloheximide, however, allows entry of 60 percent of newly synthesized G mRNA into membrane-bound polysomes. Furthermore, prelabeled G mRNA associated with membrane-bound polysomes is released from the membrane fraction in vivo by pactamycin or mucomycon A and in vitro by 1mM puromycin - 0.5 M KCI. This release is not due to nonspecific effects of the drugs. These results demonstrate that association of G mRNA with membrane-bound polysomes is dependent upon polysome formation and initiation of protein synthesis. Therefore, direct association of the 3' end of G mRNA with the membrane does not appear to be the initial event in the formation of membrane-bound polysomes.