Epstein-barr virus-specific RNA. II. Analysis of polyadenylated viral RNA in restringent, abortive, and prooductive infections.

The complexity and abundance of Epstein-Barr (EBV)-specific RNA in cell cultures restringently, abortively, and productively infected with EBV has been analyed by hybridization of the infected cell RNA with purified viral DNA. The data indicate the following. (i) Cultures containing productively infected cells contain viral RNA encoded by at least 45% of EBV DNA, and almost all of the species of viral RNA are present in the polyadenylated and polyribosomal RNA fractions. (ii) Restringently infected Namalwa and Raji cultures, which contain only intranuclear antigen, EBNA, and enhanced capacity for growth in vitro, contain EBV RNA encoded by at least 16 and 30% of the EBV DNA, respectively. The polyadenylated and polyribosomal RNA fractions of Raji and Namalwa cells are enriched for a class of EBV RNA encoded by approximately 5% of EBV DNA. The same EBV DNA sequences encode the polyadenylated and polyribosomal RNA of both Raji and Namalwa cells. (iii) After superinfection of Raji cultures with EBV (HR-1), the abortively infected cells contain RNA encoded by at least 41% of EBV DNA. The polyadenylated RNA of superinfected Raji cells is enriched for a class of EBV RNA encoded by approximately 20% of EBV HR-1 DNA. Summation hybridization experiments suggest that the polyadenylated RNA in superinfected Raji cells is encoded by the same DNA sequences as encode RNA present in Raji cells before superinfection, most of which is not polyadenylated. That the same EBV RNA sequences are present in the polyadenylated and polyribosomal fractions of two independently derived, restringently infected cell lines suggests that these RNAs may specify functions related to maintenance of the transformed state. The complexity of this class of RNA is adequate to specify a sequence of a least 5,000 amino acids. That only some RNA species are polyadenylated in restringent and abortive infection suggests that polyadenylation or whatever determines polyadenylation may play a role in the restricted expression of the EVB genome.     

Use of specific single stranded DNA probes cloned in M13 to study the RNA synthesis of four temperature-sensitive mutants of HK/68 influenza virus.

Specific single stranded DNA probes have been obtained for both influenza virion RNA (vRNA) and complementary RNA (cRNA) by cloning a hemagglutinin gene fragment in the single stranded DNA phase M13. These probes were used for hybridization with the total labeled RNA from cytoplasmic extracts of infected cells. MDCK cells were infected with temperature-sensitive mutants of influenza HK/68 and the production of the virus specific RNA species was analysed at both permissive and restrictive temperatures. Results show that two NP mutants which undergo intracistronic complementation exhibit two different phenotypes at the non permissive temperature: ts2C is poly A cRNA and vRNA negative whereas ts463 is RNA positive. Two mutants of P genes were also analysed and we discuss the relationship existing between the synthesis of the three RNA species especially between poly A and non poly A cRNA.     

The synthesis and turnover of virus-specific polyadenylated RNA in polyoma-infected cells.

Mouse embryo cells infected with the 3049 strain of polyoma virus contain several fold more virus-specific, polyadenylated RNA beginning between 4 and 8 hours after the onset of viral DNA synthesis than do cells infected with wild-type virus (lpS). Following infection with either virus strain, there is an identical small but significant enhancement of the level of total polyadenylated RNA measured by binding of ¹²⁵I-labeled RNA to poly(dT)cellulose. The polyadenylation of “early” virus-specific RNA is inhibited 85–90% by cordycepin resulting in an “early” RNA preparation which competes fully with polyadenylated “early” virus-specific RNA in the ternary complex assay. Utilizing the nonpolyadenylated “early” RNA, competition hybridization demonstrated that approximately 78% of the enlarged pool of “late” 3049 polyadenylated RNA and 72% of the “late” lpS pool consisted of sequences unique to the “late” period. No significant difference in the rate of decay of 3049 and lpS-specific, “late” polyadenylated RNA following actinomycin D block was found. Infection by either strain of polyoma virus did not alter the rate of decay of total polyadenylated RNA.     

Simian virus 40 cRNA is processed into functional mRNA in microinjected monkey cells.

Monkey cells, microinjected with simian virus 40 (SV40) in vitro synthesized cRNA produce full-size tumor (T)-antigen. This was verified by analyzing immunoprecipitates of microinjected cells by polyacrylamide gel electrophoresis. Early SV40 DNA contains an intron within the large T-antigen coding sequences. Therefore, cRNA copied in vitro from the early DNA strand requires removal of the intron in order to become a functional mRNA. Polyadenylation of the cRNA in vitro by Escherichia coli poly(A)-polymerase increased the biological activity of the RNA. Detection of T-antigen by gel electrophoresis required as little as 50 poly(A)-cRNA injected cells. Splicing of the microinjected cRNA appears to be a nuclear process. Cells enucleated by cytochalasin B prior to injection do not synthesize large T-antigen. However, small t-antigen, a protein with a continuous sequence, is synthesized in these cells. Finally, it is shown that the process of splicing is not required for the transport of mRNA from the nucleus into the cytoplasm. Authentic T-antigen mRNA, isolated from virus infected cells, induced T-antigen synthesis with similar efficiency after either nuclear or cytoplasmic injection.     

Preferential degradation of polyadenylated and polyuridinylated RNAs by the bacterial exoribonuclease polynucleotide phosphorylase.

Polyadenylation of mRNA has been shown to target the RNA molecule for rapid exonucleolytic degradation in bacteria. To elucidate the molecular mechanism governing this effect, we determined whether the Escherichia coli exoribonuclease polynucleotide phosphorylase (PNPase) preferably degrades polyadenylated RNA. When separately incubated with each molecule, isolated PNPase degraded polyadenylated and non-polyadenylated RNAs at similar rates. However, when the two molecules were mixed together, the polyadenylated RNA was degraded, whereas the non-polyadenylated RNA was stabilized. The same phenomenon was observed with polyuridinylated RNA. The poly(A) tail has to be located at the 3' end of the RNA, as the addition of several other nucleotides at the 3' end prevented competition for polyadenylated RNA. In RNA-binding experiments, E. coli PNPase bound to poly(A) and poly(U) sequences with much higher affinity than to poly(C) and poly(G). This high binding affinity defines poly(A) and poly(U) RNAs as preferential substrates for this enzyme. The high affinity of PNPase for polyadenylated RNA molecules may be part of the molecular mechanism by which polyadenylated RNA is preferentially degraded in bacterial cells.     

Purification of influenza viral complementary RNA: its genetic content and activity in wheat germ cell-free extracts.

Influenza viral complementary RNA (cRNA) was purified free from any detectable virion-type RNA (vRNA), and its genetic content and activity in wheat germ cell-free extracts were examined. After phenol-chloroform extraction of cytoplasmic fractions from infected cells, poly(A)-containing viral cRNA is found in two forms: in single-stranded RNA and associated with vRNA in partially and fully double-stranded RNA. To purify single-stranded cRNA free of these double-stranded forms, it was necessary to employ, as starting material, RNA fractions in which cRNA was predominantly single stranded. Two RNA fractions were successfully employed as starting material: polyribosomal RNA and the total cytoplasmic RNA from infected cells treated with 100 mug of cycloheximide (CM) per ml at 3 h after infection. In WSN virus-infected canine kidney (MDCK) cells, the addition of CM at 3 h after infection stimulates the production of cRNA threefold and causes a very large increase in the proportion of the cytoplasmic cRNA which is single stranded; double-stranded RNA forms are greatly reduced in amount. Total cRNA was obtained by oligo(dT)-cellulose chromatography, and single-stranded cRNA was separated from double-stranded forms by Sepharose 4B chromatography. The cRNA preparation purified from polyribosomes consists of 95% single-stranded cRNA, with the remaining 5% apparently being double-stranded RNA forms. The cRNA preparation purified from CM-treated cells (CM cRNA) is even more pure: 100% of the radiolabeled RNA is single-stranded cRNA. Annealing experiments, in which a limited amount of 32P-labeled genome RNA was annealed to the cRNA, indicate that the purified cRNA contains at least 84 to 90% of the genetic information in the vRNA genome. Purified viral cRNA (CM cRNA) is very active in directing the synthesis of virus-specific proteins in wheat germ cell-free extracts.     

The segments of influenza viral mRNA.

Influenza viral mRNA, i.e., complementary RNA (cRNA), isolated from infected cells , was resolved into six different species by electrophoresis in 2.1% acrylamide gels containing 6 M urea. The cRNA''s were grouped into three size classes: L (large), M (medium-size), and S (small). Similarly, when gels were sliced for analysis, the virion RNA (vRNA) also distributed into six peaks because the three largest vRNA segments were closely spaced and were resolved only when the gels were autoradiographed or stained. Because of their attached polyadenylic acid [poly(A)]sequences, the cRNA segments migrated more slowly than did the corresponding vRNA segments during gel electrophoresis. After removal of the poly(A) by RNase H, the cRNA and vRNA segments comigrated, indicating that they were approximately the same size. One of the cRNA segments, S2, was shown by annealing to contain the genetic information in the vRNA segment with which it comigrated, strongly suggesting that each cRNA segment was transcribed from the vRNA segment of the same size. In contrast to the vRNA segments, which when isolated from virions were present in approximately 1:1 molar ratios, the segments of the isolated cRNA were present in unequal amounts, with the segments M2 and S2 predominating, suggesting that different amounts of the cRNA segments were synthesized in the infected cell. The predominant cRNA segments, M2 and S2, and also the S1 segment, were active as mRNA''s in wheat germ extracts. The M2 cRNA was the mRNA for the nucleocapsid protein; S1 for the membrane protein; and S2 for the nonstructural protein NS1.     

Polyadenylated RNA from Vicia faba meristematic root cells. Localization and size estimation of the poly (A) segment.

After incubating root apices from two-day-old bean seedlings with [3H] adenine the RNA was extracted from whole cells or polysomes, and the poly (A) sequences were isolated by nuclease digestion followed by poly(U)-Sepharose chromatography. The alterations of the RNA molecules due to the various treatments were monitored by sucrose density gradients. It was found that sequential extraction first at pH 7.6 then at pH 9.0 did not result in a separation between RNA poor in poly(A) sequences and poly(A)-rich RNA. Furthermore chromatography analysis of hydrolysates from nuclease-resistant RNA extracted either at pH 7.6 or pH 9.0 revealed that AMP constituted nearly 95% of the bases and that the poly(A) sequences, about 200 bases, were located at the 3' terminus of the polyadenylated RNA. No size difference was found for the poly(A) segment between the pH-7.6-extracted RNA and that extracted at pH 9.0.     

The poly(A)(+)RNA sequence complexity is also represented in poly(A)(-)RNA in sea-urchin embryos

The extent to which the poly(A)(+)RNA sequence complexity from sea-urchin embryos is also represented in poly(A)(-)RNA was determined by cDNA cross-hybridization. Eighty percent or more of both the cytoplasmic poly(A)(+)RNA and polysomal poly(A)(+)RNA sequences appeared in a poly(A)(-) form. In both cases, the cellular concentrations of the poly(A)(-)RNA molecules that reacted with the cDNA were similar to the concentrations of the homologous poly(A)(+) sequences. Additionally, few, if any, abundant poly(A)(+)mRNA molecules were quantitatively discriminated by polyadenylation, since the abundant poly(A)(+)sequences were also abundant in poly(A)(-)RNA. Neither degradation nor inefficient binding to oligo (dT)-cellulose can account for the observed cross-reactivity. These data indicate that, in sea-urchin embryos, the poly(A) does not regulate the utilization of mRNA by demarcating an mRNA subset that is specifically and completely polyadenylated.     

Polyadenylate-deficient analogues of poly(A)-containing mRNA sequences in cultured AKR mouse embryo cells

Five to six percent (by mass) of AKR-2B mouse embryo cell polysomal RNA consists of messenger RNA sequences which may exist in polyadenylated form. In the steady state, however, only 30–40% of these molecules are retained by extensive passage over oligo(dT)-cellulose, the remainder being present in the form of poly(A)-deficient analogues. Within experimental limits, these poly(A)-deficient analogues contain representatives of all poly(A)-containing mRNA sequences in these cells. An analysis of the kinetics of hybridization of cDNA probes enriched for either abundant or rare poly(A)-containing mRNA sequences suggests that the frequency distributions of poly(A)-containing and poly(A)-deficient analogues are dissimilar, and that a relationship exists between the intracellular frequency of a given mRNA sequence and the number of poly(A)-deficient analogues of that sequence. High frequency sequences appear to be enriched in the poly(A)-containing fraction, while low frequency sequences are predominately associated with the poly(A)-deficient fraction, thus, poly(A) may play a role in the regulation of mRNA frequency in the cytoplasm.     

Comparative analysis of polyadenylated RNA complexity in soybean hypocotyl tissue and cultured suspension cells

Growth parameters of suspension culture cells of soybean (Glycine max L.) were compared between cells grown in medium with (+) auxin and without (−) auxin. Growth rates were greater for (+) auxin cells. Cells transferred to (−) auxin medium primarily expanded in size while (+) auxin cells initially divided and then expanded. Two methods were used to estimate polyadenylated RNA sequence complexity. Kinetic analysis gave a sum of component complexity values of 36,000 and 64,000 diverse poly(A) RNA sequences of about 1,400 nucleotides in (+) and (−) auxin grown cells, respectively. The most striking difference between these cell populations was the increase in the poly(A) RNA sequence complexity in cells grown in medium without auxin. RNA complexities were also determined by the saturation of `single' copy DNA by poly(A) RNAs from (+) and (−) auxin suspension cells. These saturation studies estimated the total complexity of (+) and (−) auxin suspension cells as 41,000 and 57,000 diverse sequences, respectively. Suspension cells in auxin-depleted medium produced about 20,000 more diverse sequences than (+) auxin cells. Comparisons of poly(A) complexities were also made among auxin-treated and untreated hypocotyl cells from the intact plant relative to suspension culture cells. Mixed populations of poly(A) RNA from these tissues and cells allowed the determination of shared sequences among them. When all combinations of poly(A) RNA were mixed, the percentage of `single' copy DNA that saturated was equivalent to diverse sequence complexity estimates of about 60,000. When mixed poly(A) RNA from suspension cells from (+) and (−) auxin medium were compared, they shared about 40,000 sequences and (−) auxin cells contained an additional 20,000. Both (+) and (−) tissue culture cells shared a subset of about 20,000 sequences with cells from (+) and (−) auxin treated hypocotyl. A third subset of about 20,000 sequences was shared by (−) auxin suspension cells and hypocotyl treated with or without auxin, a subset most of which were not shared by (+) auxin suspension cells. Kinetic and saturation data estimates of poly(A) RNA complexity compared favorably and indicated that exogenous auxin treatment can dramatically alter the complexity of all classes of poly(A) RNAs in cultured cells.