Properties of feline leukemia virus. III. Analysis of the RNA.

The kinetics of virus labeling was used to study the maturation of viral RNA in the Rickard strain of feline leukemia virus. Viral RNA labeled over differing intervals was characterized by gel electrophoresis and velocity sedimentation in sucrose gradients made up in aqueous buffer and 99% dimethyl sulfoxide. Labeled virus was found within 30 min after adding radioactive uridine to the cells and production of labeled virus reached a maximum at 4 to 5 h after pulse labeling. Native RNA from feline leukemia virus resolved into three size classes when analyzed by electrophoresis on 2.0% polyacrylamide-0.5% agarose gels: a 6.2 x 10(6) to 7.1 x 10(6) mol wt (50 to 60S) class, an 8.7 x 10(4) mol wt (approximately 8S) class, and a 2.5 x 10(4) mol wt (4 to 5S) class. From two experiments during which RNA degradation appeared minimal, these made up to 57 to 76%, 2 to 5%, and 6 to 12%, respectively, of the total RNA. The 8S RNA in feline leukemia virus has not previously been reported. The 50 to 60S RNA from virus harvested after 4 h of labeling electrophoretically migrated faster and sedimented more slowly in sucrose gradients than did the same RNA species harvested after 20 h of labeling. This argues for an intravirion modification of the high-molecular-weight RNA. The large subunits of denatured viral RNA from both 4- and 20-h labeled-viral RNA electrophoretically migrated with an estimated molecular weight of 3.2 x 10(6) but sedimented with 28S ribosomal RNA (1.8 X 10(6) mol wt) when analyzed by velocity sedimentation through 99% dimethyl sulfoxide.     

Methylation of high-molecular-weight subunit RNA of feline leukemia virus.

The high-molecular-weight subunit RNA of feline leukemia virus (Rickard strain) (FeLV-R) was analyzed for the presence of methyl groups. After purification of native 50-60S FeLV-R RNA on nondenaturing aqueous sucrose density gradients. FeLV-R 28S subunit RNA, doubly labeled with [14C]uridine and [methyl-3H]methionine, was isolated by centrifugation through denaturing sucrose density gradients in dimethyl sulfoxide. As calculated from their respective 3H/14C ratios. FeLV-R 28S RNA was methylated to the same degree as host cell poly(A)+ mRNA. When the 28S FeLV-R RNA was hydrolyzed to completion with RNase T2 or alkali, all of the methyl-3H chromatographed with mononucleotides on Pellionex-WAX, a weak anion exchanger. The methyl-labeled material co-chromatographed with 6-methyladenosine if the mononucleotide fraction obtained by Pellionex-WAX chromatography was hydrolyzed to nucleosides by bacterial alkaline phosphatase or with 6-methyladenine if purine bases were released from the mononucleotides by acid hydrolysis. In another experiment in which FeLV-R 28S RNA uniformly labeled with 32P was hydrolyzed and then analyzed by Pellionex-WAX chromatography, all of the 32P label again co-chromatographed with mononucleotides. Thus FeLV-R 28S RNA does not appear to contain a 5' structure, either methylated or nonmethylated similar to those recently reported for cellular and some animal virus mRNA's.     

Molecular Weight Determination of Sendai and Newcastle Disease Virus RNA

The molecular weights of Sendai and Newcastle disease virus RNA were estimated by sedimentation in sucrose gradients and by length measurements in the electron microscope under both denaturing and nondenaturing conditions. Sedimentation analyses under denaturing conditions yielded molecular weight estimates of 2.3 x 10(6) to 2.6 x 10(6), whereas length measurements yielded estimates of 5.2 x 10(6) to 5.6 x 10(6) for both denatured and nondenatured viral RNA. It would appear that the conditions of denaturation used (99% dimethyl sulfoxide at 26 C, and reaction with 1.1 M formaldehyde for 10 min at 60 C) do not equally denature parainfluenza virus RNA and other RNAs, such as cellular rRNA, 45S rRNA precursor, and R17 RNA.     

Murine oncornavirus high-molecular-weight RNA structure thermal stepwise dissociation of 70S murine leukemia-sarcoma virus to subunits and low-molecular-weight associated RNAs.

The thermal dissociation into subunits and low-molecular-weight (LMW) associated RNAs of the aggregate structure of 70S RNA of a murine leukemia sarcoma viral complex was studied. By polyacrylamide-agarose gel electrophoresis, it was found that at low temperature a fraction of the genome was converted into an intermediate population of RNA (Im.P) with an apparent molecular weight of 6.6 times 10-6. At higher temperature, the 70S RNA and the Im.P RNA were successively dissociated into two RNA subunits called "I" and "II" and 70S-associated LMW RNAs. The apparent molecular weight of subunit I was about 5 times 10-6 and that of subunit II was about 3.2 times 10-6. The release of 4S, 5S, 5.5S, and 8S RNAs from 70S RNA at various temperatures was studied by composite polyacrylamide gel electrophoresis. It was found that the nature of hydrogen bonding to the 70S RNA was different for each LMW RNA species. A possible relationship of the association between the subunits and each 70S-associated LMW RNA, based on their T-m values, is discussed.     

RNA subunit structure of Mason-Pfizer monkey virus.

Mason-Pfizer monkey virus 60-70S RNA has a molecular weight of 8 times 10-6 when analyzed on polyacrylamide gels. Dissociation of 60-70S RNA of Mason-Pfizer monkey virus and murine leukemia virus by heat or formamide (40%) resulted in conversion to identical subunit structures of 2.8 times 10-6 daltons; treatment with lower amounts of formamide revealed a partial dissociation of Mason-Pfizer monkey virus 60-70S RNA released three low-molecular-weight RNA species of 10-5, 3,5 times 10-4, and 2.5 times 10-4.     

Role of Subunits of 60 to 70S Avian Tumor Virus Ribonucleic Acid in Its Template Activity for the Viral Deoxyribonucleic Acid Polymerase

Heating the 60 to 70S ribonucleic acid (RNA) of Rous sarcoma virus (RSV) destroys both its subunit structure and its high template activity for RSV deoxyribonucleic acid (DNA) polymerase. In comparative analyses, it was found that the template activity of the RNA has a thermal transition of 70 C, whereas the 60 to 70S structure dissociates into 30 to 40S and several distinct small subunits with a T(m) of 55 C. Analysis by velocity sedimentation and isopycnic centrifugation of the primary DNA product obtained by incubation of 60 to 70S RSV RNA with RSV DNA polymerase indicated that most, but perhaps not all, DNA was linked to small (<10S) RSV RNA primer. Sixty percent of the high template activity of 60 to 70S RSV RNA lost after heat dissociation could be recovered by incubation of the total RNA under annealing conditions. The template activity of purified 30 to 40S subunits isolated from 60 to 70S RSV RNA was not enhanced significantly by annealing. However, in the presence of small (<10S) subunits also isolated from 60 to 70S RNA, the template activity of 30 to 40S RNA subunits was increased to the same level as that of reannealed total 60 to 70S RNA. It was concluded that neither the 30 to 40S subunits nor most of the 4S subunits of 60 to 70S RSV RNA contribute much as primers to the template activity of 60 to 70S RSV RNA. The predominant primer molecule appears to be a minor component of the <10S subunit fraction of 60 to 70S RSV RNA. Its electrophoretic mobility is similar to, and its dissociation temperature from 60 to 70S RSV RNA is higher than that of the bulk of 60 to 70S RSV RNA-associated 4S RNA. The role of primers in DNA synthesis by RSV DNA polymerase is discussed.     

Intracellular distribution and sedimentation properties of virus-specific RNA in two clones of BHK cells transformed by polyoma virus.

The virus-specific RNA in two independently derived clones of polyoma virus-transformed hamster cells was studied by hybridizing labeled RNA, with excess purified polyoma DNA, immoblized on filters. In one clone (PyBHK1), less than 25% of the total labeled virus-specific RNA was found in the cytoplasm, irrespective of the labeling time. In the other clone (PyBHK2), it was estimated that 39% of the total virus-specific RNA was present inthe cytoplasm after labeling for 3 h. Both the proportion of radioactive label incorporated into virus-specific RNA and the sedimentation pattern of total virus-specific RNA differed markedly between PyBHK and PyBHK2. Most of the virus-specific RNA of PyBHK1 sedimented in the range 25S-35S, whereas a prominent 18S component was present in PyBHK2. Most of the cytoplasmic virus-specific RNA in both clones sedimented at 18S-19S. The sedimentation patterns of virus-specific RNA from whole cells and from washed nuclei of PyBHK1 were closely similar: it was estimated from sedimentation analysis in dimethyl sulfoxide that the molecular weight of 50% of this RNA was within the range 1.1 X10(6) to 2.9 X 10(6). These results, demonstrating the accumulation of virus-specific RNA within the nucleus in at least one virus-transformed cell line, indicate that the large virus-specific RNA previously described in the nuclei of transformed cells may not have represented precursors of virus-specific mRNA.     

Low-molecular-weight (4.5S) ribonucleic acid in higher-plant chloroplast ribosomes.

A species of RNA that migrates on 10% (w/v) polyacrylamide gels between 5S and 4S RNA was detected in spinach chloroplasts. This RNA (referred to as 4.5 S RNA) was present in amounts equimolar to the 5S RNA and its molecular weight was estimated to be approx. 33 000. Fractionation of the chloroplast components showed that the 4.5S RNA was associated with the 50 S ribosomal subunit and that it could be removed by washing the ribosomes with a buffer containing 0.01 M-EDTA and 0.5 M-KCl. It did not appear to be a cleavage product of the labile 23 S RNA of spinach chloroplast ribosomes. When 125I-labelled 4.5 S RNA was hybridized to fragments of spinach chloroplast DNA produced by SmaI restriction endonuclease, a single fragment (mol.wt. 1.15 times 10(6)) became labelled. The same DNA fragment also hybridized to chloroplast 5 S RNA and part of the 23 S RNA. It was concluded that the coding sequence for 4.5 S RNA was part of, or immediately adjacent to, the rRNA-gene region in chloroplast DNA . A comparable RNA species was observed in chloroplasts of tobacco and pea leaves.     

Replication of Sindbis Virus V. Polyribosomes and mRNA in Infected Cells

Cells infected with wild-type Sindbis virus contain at least two forms of mRNA, 26S and 49S RNA. Sindbis 26S RNA (molecular weight 1.6 x 10(6)) constitutes 90% by weight of the mRNA in infected cells, and is thought to specify the structural proteins of the virus. Sindbis 49S RNA, the viral genome (molecular weight 4.3 x 10(6)), constitutes approximately 10% of the mRNA in infected cells and is thought to supply the remaining viral functions. In cells infected with ts2, a temperature-sensitive mutant of Sindbis virus, the messenger forms also include a third species of RNA with a sedimentation coefficient of 33S and an apparent molecular weight of 2.3 x 10(6). Hybridization-competition experiments showed that 90% of the base sequences in 33S RNA from these cells are also present in 26S RNA. Sindbis 33S RNA was also isolated from cells infected with wild-type virus. After reaction with formaldehyde, this species of 33S RNA appeared to be completely converted to 26S RNA. These results indicate that 33S RNA isolated from cells infected with either wild-type Sindbis or ts2 is not a unique and separate form of Sindbis RNA.     

Refined molecular weights for phage, viral and ribosomal RNA.

The RNAs of the Escherichia coli bacteriophages MS2 and Qbeta as well as E. coli 16S ribosomal RNA were examined under identical conditions by electron microscopy using the protein-free benzyldimethylalkylammonium chloride (BAC) spreading technique. From the contour length ratios of the RNAs and the known number of nucleotides for MS2, the chain lengths for Qbeta RNA and 16S RNA were found to be 4790 +/- 150 and 1645 +/- 55 nucleotides. Correcting for the base composition of Qbeta RNA the molecular weight of the Na salt of this RNA is (1.64 +/- 0.06) . 10(6) daltons. Since published values on the relative lengths of Qbeta RNA and several other homogeneous RNAs (E. coli 23S rRNA, E. Coli bacteriophage R17 and f2 RNAs, Pseudomonas aeruginosa phage PP7 RNA and Newcastle disease virus RNA) are available, we are able to calculate the approximate number of nucleotides for these useful standards.     

Structural Rearrangement and Subunit Composition of RNA from Released Soehner-Dmochowski Murine Sarcoma Virions

Two types of genomic, high-molecular-weight RNA species were found in Soehner-Dmochowski murine sarcoma virions released from virus-induced rat tumor cells grown in tissue culture. The type of RNA species observed depended on the length of exposure of the tumor cells to radioactive precursor. Early RNA of virions labeled up to 4 h with radioactive uridine had a sedimentation coefficient of 50S, and late RNA of virions labeled for 24 h had a sedimentation coefficient of 58S. Thermal transitions of early and late RNA indicated a difference in the configuration or structure of these two types of RNA. The late RNA may represent either a different configurational state of the early RNA or an aggregate molecule of two early RNA components joined together. Heat dissociation revealed that the major subunit of both RNA types was a 28S species, which was not susceptible to degradation by the addition of micrococcal nuclease to virions. A transitional, intermediate RNA species with a sedimentation coefficient of 37 to 40S was detected when early RNA was dissociated by dimethyl sulfoxide or heat at temperatures suboptimal for complete conversion. No free RNA subunit components were detected in virions harvested at intervals as short as 30 s or 5 min. A model for the assembly of genomic RNA from 28S RNA subunits is proposed.     

Molecular Weight Determination of Sendai RNA by Dimethyl Sulfoxide Gradient Sedimentation

The molecular weight of the large RNA of Sendai virus has been determined by sedimentation analysis in sucrose gradients containing 99% dimethyl sulfoxide (DMSO) to be 2.3 × 10⁶. Sendai RNA recovered from 99% DMSO was found to cosediment with nondenatured Sendai RNA at 46 to 48s in ordinary sucrose gradients. The molecular weight value of 2.3 × 10⁶ is considerably smaller than the estimates of 6 × 10⁶ to 7 × 10⁶ determined under nondenaturing conditions, suggesting a unique structure for Sendai RNA.     

Caenorhabditis elegans: purification of isocitrate lyase and the isolation and cell-free translation of poly(A+)RNA

Isocitrate lyase (EC 4.1.3.1) from mixed larval populations of Caenorhabditis elegans was stabilized in crude extracts by centrifugation over a 0.2-0.6 M sucrose gradient for 2.5 hr in a vertical rotor (VTi 50) at 210,000g. The peak fractions from this sucrose gradient showed a half-life of 33 hr at 30 C and 225 hr at 4 C in contrast to 2.5 and 52 hr, respectively, for the crude extract. A purification scheme involving (NH4)2SO4 precipitation and chromatography on Sepharose 6B and diethylaminoethyl-cellulose yielded isocitrate lyase that gave one band after electrophoresis in a sodium dodecyl sulfate-gel polymerized from 12% acrylamide. The purified enzyme with a molecular weight of 250,000 and subunit molecular weight of 61,600, had a specific activity of 2 mumoles glyoxylate formed min-1 mg protein-1, and was obtained in a 4% yield. Isocitrate lyase from C. elegans lost 80-85% of its activity in the precipitation by 33-55% (NH4)2SO4, but this step appeared to be necessary for purification to homogeneity. The use of fast protein liquid chromatography appeared to be promising in that it provided an enzyme preparation that was about 50% pure with a specific activity as high as 3 mumoles glyoxylate formed min-1 mg protein-1. Poly(A+)RNA was isolated from C. elegans and translated in wheat germ cell-free system. Analysis on a 10% sodium dodecyl sulfate-polyacrylamide gel showed varied translation products including one or more 60,000-Da polypeptides.     

Cell-free translation of virion RNA from nondefective and transformation-defective Rous sarcoma viruses.

Nondefective and transformation-defective virion subunit RNAs from two strains of Rous sarcoma virus (RSV) were translated in cell-free systems derived from Krebs IIA ascites cells, wheat germ, and L-cells. In each case the predominant viral-specific product was a polypeptide of molecular weight 76,000 that is related to the internal viral group-specific antigens, as judged by immunoprecipitation with monospecific antisera and tryptic peptide fingerprinting. No difference could be detected between the translation products of 35S RNA from nondefective and transformation-defective RSV virions, nor of 35S RNA from different strains of RSV. The 76,000-molecular-weight polypeptide synthesized in response to 35S RNA in vitro was labeled with formyl-methionine from initiator tRNA. Models for viral protein synthesis are discussed in the light of these results, and arguments positioning the group-specific antigen gene at the 5' end of the 35S RNA are presented.     

Two types of rat gastric mucus glycoprotein subunits

Gastric mucus glycoproteins were extracted with 2% Triton X-100 from rat gastric corpus and antrum and purified by CsCl equilibrium centrifugation. Corpus mucus glycoproteins were degraded into what appeared to be two "subunits" (Mw 4.4 x 10(5) and 6 x 10(6)) by the reduction of disulfide bonds. Papain digestion of the latter produced glycopeptides with a molecular weight of approximately 4.4 x 10(5). This type of subunit had carbohydrate chains with about 9 sugars attached to every 2 amino acid residues. Papain digestion of the former type of subunit revealed no change in the elution profile on Bio-Gel A-15m. This type of subunit had carbohydrate chains with 17-19 sugars attached to every 3 amino acid residues. The subunit of antral mucus glycoproteins was essentially the same as the former type of corpus subunits in molecular weight (Mw 4.4 x 10(5)) and average oligosaccharide chain length. These results suggest that there are two distinct types of mucus glycoprotein subunits in rat stomach.     

Identification of RNAase-sensitive 20S RNA in a cell culture infected with Sindbis virus]

RNAse-sensitive 20S RNA component with molecular weight of 0.7-10(6) is found when analysing virus-specific RNAs isolated from cultured chicken embryo fibroblasts infected with Sindbis virus by means of gradient centrifugation and polyacrylamide gel electrophoresis.     

Molecular Weight of Poliovirus Ribonucleic Acid

Purified poliovirus single- and double-stranded ribonucleic acids (RNA) were examined by electron microscopy. The length of both molecules was found to be 2.37 mum. The uncorrected sedimentation coefficient for single-stranded RNA is 33S, as compared to 27S for the RNA of tobacco mosaic virus. It is calculated from these results that the molecular weight of the sodium form of poliovirus is 2.6 x 10(6) daltons.     

Ribonucleic acid synthesis and loss of viability in pea seed

Summary RNA synthesis and protein synthesis in embryonic axis tissue of viable pea (Pisum arvense L. var. N.Z. maple) seed commences during the first hour of germination. Protein synthesis in axis tissue of non-viable pea seed is barely detectable during the first 24 h after the start of imbibition. Nonviable axis tissue incorporates significant levels of [³H]uridine into RNA during this period but the level of incorporation does not increase significantly over the first 24 h of imbibition. In axis tissue of non-viable seed during the first hour of imbibition most of the [³H]uridine was incorporated into low molecular weight material migrating in advance of the 4S and 5S RNA species in polyacrylamide gels but some radioactivity was incorporated into a discrete species of RNA having a molecular weight of 2.7×10⁶. After 24 h, non-viable axis tissue incorporates [³H]uridine into ribosomal RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and a heterogeneous RNA species of molecular weight ranging from 2.2×10⁶ to 2.7×10⁶. No 4S or 5S RNA synthesis is detectable after 24 h of imbibition in non-viable axis tissue. Axis tissue of viable pea seed synthesises rRNA, 4S and 5S RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and the rRNA precursor species at both periods of germination studied. Loss of viability in pea seed appears to be accompanied by the appearance of lesions in the processing of rRNA precursor species and a significant loss of RNA synthesising activity.Abbreviations rRNA ribosomal RNA - TCA trichloroacetic acid - SLS sodium lauryl sulphate - PPO 2,5 Diphenyloxazole - POPOP 1,4-Bis-2-(4-methyl-5-penyloxazolyl)-benzene     

Molecular Weight of Two Oncornavirus Genomes: Derivation from Particle Molecular Weights and RNA Content

Sedimentation analysis and intensity fluctuation spectroscopy have been used in conjunction with the Svedberg equation to determine the particle molecular weights of Rous sarcoma virus (Prague strain) and avian myeloblastosis virus (BAI strain). The molecular weights of these two viruses are (294 +/- 20) x 10(6) and (256 +/- 18) x 10(6), respectively. Values for the molecular weight of the RNA contained in each particle have been calculated as (5.58 +/- 0.5) x 10(6) and (5.88 +/- 0.5) x 10(6). Since the proportion of the viral RNA represented by 4 to 7S low-molecular-weight material is known, the molecular weight of the 60 to 70S genomes may be calculated to lie in the range (3.8 +/- 0.3 to 4.8 +/- 0.4) x 10(6) for both particles. These estimates for the molecular weight of the 60 to 70S genome are much lower than previous estimates and fall within the range of current estimates of the size of a single 35S subunit. The implications of this finding are discussed in terms of current theories for the structure of the genome of RNA tumor viruses.     

Process of infection with bacteriophage phiX174. XXXVII. RNA metabolism in phiX174-infected cells.

The RNA produced in vivo from bacteriophage phiX174 DNA has been analyzed by polyacrylamide-agarose gel electrophoresis and sedimentation in dimethyl sulfoxide gradients, and the results of Hayashi and Hayashi (1970) have been confirmed and extended. An efficient procedure for recovery of RNA from gels, followed by a hybridization assay, has indicated the presence in infected cells of 18 distinct RNA species with sizes up to and greater than the unit (viral) length. The sizes of phiX mRNA's were similar irrespective of whether material was analyzed on gels or in dimethyl sulfoxide gradients. When virus-induced RNA was detected by a double-label method, seven additional low-molecular weight species were observed on gels and the resolution of dimethyl sulfoxide gradients was enhanced. The present results lend support to aspects of the model of Hayashi and Hayashi (1970) for the generation of these discrete mRNA species; an alternative model is also discussed.