Synthesis of influenza virus polypeptides in cells resistant to alpha-amanitin: evidence for the involvement of cellular RNA polymerase II in virus replication

The Influenza Virus RNA-Polymerase and the Host RNA-Polymerase II: RPB4 Is Targeted by a PB2 Domain That Is Involved in Viral Transcription

Influenza virus transcription is catalyzed by the viral RNA-polymerase (FluPol) through a cap-snatching activity. The snatching of the cap of cellular mRNA by FluPol is preceded by its binding to the flexible C-terminal domain (CTD) of the RPB1 subunit of RNA-polymerase II (Pol II). To better understand how FluPol brings the 3′-end of the genomic RNAs in close proximity to the host-derived primer, we hypothesized that FluPol may recognize additional Pol II subunits/domains to ensure cap-snatching. Using binary complementation assays between the Pol II and influenza A FluPol subunits and their structural domains, we revealed an interaction between the N-third domain of PB2 and RPB4. This interaction was confirmed by a co-immunoprecipitation assay and was found to occur with the homologous domains of influenza B and C FluPols. The N-half domain of RPB4 was found to be critical in this interaction. Punctual mutants generated at conserved positions between influenza A, B, and C FluPols in the N-third domain of PB2 exhibited strong transcriptional activity defects. These results suggest that FluPol interacts with several domains of Pol II (the CTD to bind Pol II), initiating host transcription and a second transcription on RPB4 to locate FluPol at the proximity of the 5′-end of nascent host mRNA.

Influenza Virus RNA-Dependent RNA Polymerase and the Host Transcriptional Apparatus

Influenza virus RNA-dependent RNA polymerase (FluPol) transcribes the viral RNA genome in the infected cell nucleus. In the 1970s, researchers showed that viral transcription depends on host RNA polymerase II (RNAP II) activity and subsequently that FluPol snatches capped oligomers from nascent RNAP II transcripts to prime its own transcription. Exactly how this occurs remains elusive. Here, we review recent advances in the mechanistic understanding of FluPol transcription and early events in RNAP II transcription that are relevant to cap-snatching. We describe the known direct interactions between FluPol and the RNAP II C-terminal domain and summarize the transcription-related host factors that have been found to interact with FluPol. We also discuss open questions regarding how FluPol may be targeted to actively transcribing RNAP II and the exact context and timing of cap-snatching, which is presumed to occur after cap completion but before the cap is sequestered by the nuclear cap-binding complex.

The Influenza A Virus Endoribonuclease PA-X Usurps Host mRNA Processing Machinery to Limit Host Gene Expression

Many viruses shut off host gene expression to inhibit antiviral responses. Viral proteins and host proteins required for viral replication are typically spared in this process, but the mechanisms of target selectivity during host shutoff remain poorly understood. Using transcriptome-wide and targeted reporter experiments, we demonstrate that the influenza A virus endoribonuclease PA-X usurps RNA splicing to selectively target host RNAs for destruction. Proximity-labeling proteomics reveals that PA-X interacts with cellular RNA processing proteins, some of which are partially required for host shutoff. Thus, PA-X taps into host nuclear pre-mRNA processing mechanisms to destroy nascent mRNAs shortly after their synthesis. This mechanism sets PA-X apart from other viral host shutoff proteins that target actively translating mRNAs in the cytoplasm. Our study reveals a unique mechanism of host shutoff that helps us understand how influenza viruses suppress host gene expression.

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Influenza A virus PA-X targets the majority of host mRNAs for destruction

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Downregulation by PA-X correlates with the number of splice sites in a transcript

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Splicing renders RNAs susceptible to PA-X

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The cellular CFIm complex interacts with PA-X and contributes to PA-X activity

Interplay between Influenza Virus and the Host RNA Polymerase II Transcriptional Machinery

The influenza virus RNA-dependent RNA polymerase (RdRP) cleaves the 5' end of nascent capped host RNAs and uses the capped RNA fragment to prime viral transcription in a mechanism called 'cap snatching'. Cap snatching requires an intimate association between influenza RdRP and cellular RNA polymerase II (Pol II), which is the source of nascent capped host RNAs targeted by influenza virus. Recent structural studies have revealed how influenza RdRP binds to Pol II and how this binding promotes the initiation of viral transcription by influenza RdRP. In this review we focus on these recent insights into the mechanism of cap snatching by influenza virus and the impact of cap snatching on host gene expression during influenza virus infection.

Insight into Influenza: A Virus Cap-Snatching

The influenza A virus (IAV) genome consists of eight single-stranded RNA segments. Each segment is associated with a protein complex, with the 3′ and 5′ ends bound to the RNA-dependent RNA polymerase (RdRp) and the remainder associated with the viral nucleoprotein. During transcription of viral mRNA, this ribonucleoprotein complex steals short, 5′-capped transcripts produced by the cellular DNA dependent RNA polymerase II (RNAPII) and uses them to prime transcription of viral mRNA. Here, we review the current knowledge on the process of IAV cap-snatching and suggest a requirement for RNAPII promoter-proximal pausing for efficient IAV mRNA transcription.

Host Shutoff in Influenza A Virus: Many Means to an End

Influenza A virus carries few of its own proteins, but uses them effectively to take control of the infected cells and avoid immune responses. Over the years, host shutoff, the widespread down-regulation of host gene expression, has emerged as a key process that contributes to cellular takeover in infected cells. Interestingly, multiple mechanisms of host shutoff have been described in influenza A virus, involving changes in translation, RNA synthesis and stability. Several viral proteins, notably the non-structural protein NS1, the RNA-dependent RNA polymerase and the endoribonuclease PA-X have been implicated in host shutoff. This multitude of host shutoff mechanisms indicates that host shutoff is an important component of the influenza A virus replication cycle. Here we review the various mechanisms of host shutoff in influenza A virus and the evidence that they contribute to immune evasion and/or viral replication. We also discuss what the purpose of having multiple mechanisms may be.

Recognition of cap structure by influenza B virus RNA polymerase is less dependent on the methyl residue than recognition by influenza A virus polymerase

The cap-dependent endonuclease activity of the influenza virus RNA-dependent RNA polymerase cleaves host mRNAs to produce capped RNA fragments for primers to initiate viral mRNA synthesis. The influenza A virus (FluA) cap-dependent endonuclease preferentially recognizes the cap1 structure (m(7)GpppNm). However, little is known about the substrate specificity of the influenza B virus (FluB) endonuclease. Here, we determined the substrate specificity of the FluB polymerase using purified viral RNPs and (32)P-labeled polyribonucleotides containing a variety of cap structures (m(7)GpppGm, m(7)GpppG, and GpppG). We found that the FluA polymerase cleaves m(7)G-capped RNAs preferentially. In contrast, the FluB polymerase could efficiently cleave not only m(7)G-capped RNAs but also unmethylated GpppG-RNAs. To identify a key amino acid(s) related to the cap recognition specificity of the PB2 subunit, the transcription activity of FluB polymerases containing mutated cap-binding domains was examined by use of a minireplicon assay system. In the case of FluA PB2, Phe323, His357, and Phe404, which stack the m(7)GTP, and Glu361 and Lys376, which make hydrogen bonds with a guanine base, were essential for the transcription activity. In contrast, in the case of FluB PB2, the stacking interaction of Trp359 with a guanine base and putative hydrogen bonds using Gln325 and Glu363 were enough for the transcription activity. Taking these results together with the result for the cap-binding activity, we propose that the cap recognition pocket of FluB PB2 does not have the specificity for m(7)G-cap structures and thus is more flexible to accept various cap structures than FluA PB2.

Preferential use of RNA leader sequences during influenza A transcription initiation in vivo

In vitro transcription initiation studies revealed a preference of influenza A virus for capped RNA leader sequences with base complementarity to the viral RNA template. Here, these results were verified during an influenza infection in MDCK cells. Alfalfa mosaic virus RNA3 leader sequences mutated in their base complementarity to the viral template, or the nucleotides 5' of potential base-pairing residues, were tested for their use either singly or in competition. These analyses revealed that influenza transcriptase is able to use leaders from an exogenous mRNA source with a preference for leaders harboring base complementarity to the 3'-ultimate residues of the viral template, as previously observed during in vitro studies. Internal priming at the 3'-penultimate residue, as well as "prime-and-realign" was observed. The finding that multiple base-pairing promotes cap donor selection in vivo, and the earlier observed competitiveness of such molecules in vitro, offers new possibilities for antiviral drug design.

Mechanisms and functional implications of the degradation of host RNA polymerase II in influenza virus infected cells

Influenza viruses induce a host shut off mechanism leading to the general inhibition of host gene expression in infected cells. Here, we report that the large subunit of host RNA polymerase II (Pol II) is degraded in infected cells and propose that this degradation is mediated by the viral RNA polymerase that associates with Pol II. We detect increased ubiquitylation of Pol II in infected cells and upon the expression of the viral RNA polymerase suggesting that the proteasome pathway plays a role in Pol II degradation. Furthermore, we find that expression of the viral RNA polymerase results in the inhibition of Pol II transcription. We propose that Pol II inhibition and degradation in influenza virus infected cells could represent a viral strategy to evade host antiviral defense mechanisms. Our results also suggest a mechanism for the temporal regulation of viral mRNA synthesis.

Therapeutic activity of an anti-idiotypic antibody-derived killer peptide against influenza A virus experimental infection

The in vitro and in vivo activities of a killer decapeptide (KP) against influenza A virus is described, and the mechanisms of action are suggested. KP represents the functional internal image of a yeast killer toxin that proved to exert antimicrobial and anti-human immunodeficiency virus type 1 (HIV-1) activities. Treatment with KP demonstrated a significant inhibitory activity on the replication of two strains of influenza A virus in different cell lines, as evaluated by hemagglutination, hemadsorption, and plaque assays. The complete inhibition of virus particle production and a marked reduction of the synthesis of viral proteins (membrane protein and hemagglutinin, in particular) were observed at a KP concentration of 4 microg/ml. Moreover, KP administered intraperitoneally at a dose of 100 microg/mice once a day for 10 days to influenza A/NWS/33 (H1N1) virus-infected mice improved the survival of the animals by 40% and significantly decreased the viral titers in their lungs. Overall, KP appears to be the first anti-idiotypic antibody-derived peptide that displays inhibitory activity and that has a potential therapeutic effect against pathogenic microorganisms, HIV-1, and influenza A virus by different mechanisms of action.

Influenza virus infection causes specific degradation of the largest subunit of cellular RNA polymerase II

It has been described that influenza virus polymerase associates with RNA polymerase II (RNAP II). To gain information about the role of this interaction, we explored if changes in RNAP II occur during infection. Here we show that influenza virus causes the specific degradation of the hypophosphorylated form of the largest subunit of RNAP II without affecting the accumulation of its hyperphosphorylated forms. This effect is independent of the viral strain and the origin of the cells used. Analysis of synthesized mRNAs in isolated nuclei of infected cells indicated that transcription decreases concomitantly with RNAP II degradation. Moreover, this degradation correlated with the onset of viral transcription and replication. The ubiquitin-mediated proteasome pathway is not involved in virally induced RNAP II proteolysis. The expression of viral polymerase from its cloned cDNAs was sufficient to cause the degradation. Since the PA polymerase subunit has proteolytic activity, we tested its participation in the process. A recombinant virus that encodes a PA point mutant with decreased proteolytic activity and that has defects in replication delayed the effect, suggesting that PA's contribution to RNAP II degradation occurs during infection.

Influenza virus inhibits RNA polymerase II elongation

The influenza virus RNA-dependent RNA polymerase interacts with the serine-5 phosphorylated carboxy-terminal domain (CTD) of the large subunit of RNA polymerase II (Pol II). It was proposed that this interaction allows the viral RNA polymerase to gain access to host mRNA-derived capped RNA fragments required as primers for the initiation of viral mRNA synthesis. Here, we show, using a chromatin immunoprecipitation (ChIP) analysis, that similar amounts of Pol II associate with Pol II promoter DNAs in influenza virus-infected and mock-infected cells. However, there is a statistically significant reduction in Pol II densities in the coding region of Pol II genes in infected cells. Thus, influenza virus specifically interferes with Pol II elongation, but not Pol II initiation. We propose that influenza virus RNA polymerase, by binding to the CTD of initiating Pol II and subsequent cleavage of the capped 5' end of the nascent transcript, triggers premature Pol II termination.

Functional association between viral and cellular transcription during influenza virus infection

Influenza viruses replicate and transcribe their segmented negative-sense single-stranded RNA genome in the nucleus of the infected host cell. All RNA synthesising activities associated with influenza virus are performed by the virally encoded RNA-dependent RNA polymerase (RdRp) that consists of three subunits, PA, PB1 and PB2. However, viral transcription is critically dependent on on-going cellular transcription, in particular, on activities associated with the cellular DNA-dependent RNA polymerase II (Pol II). Thus, the viral RdRp uses short 5' capped RNA fragments, derived from cellular Pol II transcripts, as primers for viral mRNA synthesis. These capped RNA primers are generated by cleavage of host Pol II transcripts by an endonuclease activity associated with the viral RdRp. Moreover, some viral transcripts require splicing and since influenza virus does not encode splicing machinery, it is dependent on host splicing, an activity also related to Pol II transcription. Despite these functional links between viral and host Pol II transcription, there has been no evidence that a physical association existed between the two transcriptional machineries. However, recently it was reported that there is a physical interaction between the trimeric viral RdRp and cellular Pol II. The viral RdRp was found to interact with the C-terminal domain (CTD) of initiating Pol II, at a stage in the transcription cycle when capping takes place. It was therefore proposed that this interaction may be required for the viral RNA (vRNA) polymerase to gain access to capped RNA substrates for endonucleolytic cleavage. The virus not only relies on cellular factors to support its own RNA synthesis, but also subverts cellular pathways in order to generate an environment optimised for viral multiplication. In this respect, the interaction of the viral NS1 protein with factors involved in cellular pre-mRNA processing is of particular relevance. The virus also alters the distribution of Pol II on cellular genes, leading to a reduction in elongating Pol II thereby contributing to the phenomenon known as host shut-off.

Association of the influenza A virus RNA-dependent RNA polymerase with cellular RNA polymerase II

Transcription by the influenza virus RNA-dependent RNA polymerase is dependent on cellular RNA processing activities that are known to be associated with cellular RNA polymerase II (Pol II) transcription, namely, capping and splicing. Therefore, it had been hypothesized that transcription by the viral RNA polymerase and Pol II might be functionally linked. Here, we demonstrate for the first time that the influenza virus RNA polymerase complex interacts with the large subunit of Pol II via its C-terminal domain. The viral polymerase binds hyperphosphorylated forms of Pol II, indicating that it targets actively transcribing Pol II. In addition, immunofluorescence analysis is consistent with a new model showing that influenza virus polymerase accumulates at Pol II transcription sites. The present findings provide a framework for further studies to elucidate the mechanistic principles of transcription by a viral RNA polymerase and have implications for the regulation of Pol II activities in infected cells.

Inhibition by prostaglandin PGA1 on the multiplication of influenza virus is a dose-dependent effect

Cyclopentenone prostaglandins (PGs), are strong inhibitors of the multiplicative cycle of a wide variety of enveloped RNA and DNA viruses. Their antiviral activity is generally associated with alterations in the synthesis or maturation of specific virus proteins. In this report, we describe the effect of cyclopentenone PGA1 on the replication of influenza A virus Ulster 73 in LLC-MK2 cells. PGA1 was found to inhibit viral replication in a dose-dependent fashion and virus particle yield was reduced at a PGA1 concentration, which did not suppress protein synthesis in mock-infected cells. The kinetic of late viral protein synthesis was delayed in PGA1-treated cells till 10 h post-infection; after that period, viral polypeptide synthesis appeared to be similar in PGA1-treated as well as untreated cells both infected by Ulster 73 virus. This finding suggests that PGA1 might interfere with one or more events in the viral multiplicative cycle such as protein synthesis and assembly, correct insertion of virus polypeptides into the cell membrane and, or maturation of Ulster 73 virion particles. In particular, inhibition of viral replication in LLC-MK2 cells by PGA1 is accompanied by the induction of a cellular polypeptide of 70K molecular weight. We identified this cell protein as a heat shock protein (HSP) related to the inducible isoform of HSP 70, a polypeptide of 72K molecular weight. Induction of this polypeptide by PGA1 was found to be dose-dependent and a substantial accumulation could be seen at a PGA1 concentration that did not inhibit cell protein synthesis in uninfected cells. HSP 70 synthesis started after the beginning of PGA1 treatment and remained at the same level for at least 10 h, leading us to hypothesize that the delay of production of late Ulster 73 proteins could be the consequence of HSP 70 synthesis. These results suggest that HSP 70 could play a role in the antiviral activity of cyclopentenone PGA1 in LLC-MK2 cells.

Thogoto and Dhori virus replication is blocked by inhibitors of cellular polymerase II activity but does not cause shutoff of host cell protein synthesis

Tick-transmitted Thogoto and Dhori viruses share structural and genetic properties with the influenza viruses. Here, we compare different steps of their replication cycle in mammalian cells in comparison with influenza A virus. Viral antigens of both viruses accumulated in the nuclei of infected cells, suggesting a nuclear phase of viral replication. Furthermore, as observed with influenza viruses, transcription of Thogoto and Dhori viruses was inhibited by alpha-amanitin and actinomycin D, suggesting a dependence of viral transcription on cellular RNA polymerase II activity. In contrast to influenza viruses, Thogoto and Dhori virus infection did not lead to down-regulation of cellular protein synthesis indicating marked differences regarding the fate of infected cells.

Inhibition of influenza virus transcription by 2'-deoxy-2'-fluoroguanosine

The nucleoside analog 2'-deoxy-2'-fluoroguanosine (2'-fluorodGuo) is phosphorylated by cellular enzymes and reversibly inhibits influenza virus replication in chick embryo cells within the first 4 h of infection. RNA hybridization studies revealed that primary and secondary transcription of influenza virus RNA were blocked at a compound concentration of 10 microM, but no inhibition of cell protein synthesis was seen even at high compound concentrations (200 microM). In vitro, the triphosphate of 2'-fluorodGuo is a competitive inhibitor of influenza virus transcriptase activity from disrupted virus, with a Ki of 1.0 microM. The cellular polymerases DNA polymerase alpha and RNA polymerase II were only weakly inhibited or were insusceptible to 2'-fluorodGTP. In kinetic studies with the influenza virus transcriptase, 2'-fluorodGTP, in the absence of GTP, blocked elongation of the virus RNA chain. Similarly, by using purified ribonucleoprotein complexes it was found that the addition of a single nucleotide of 2'-fluorodGTP to the virus RNA caused chain termination, which resulted in the blockage of further virus transcription. Furthermore, the specificity for influenza virus transcriptase was confirmed when the transcriptase from partially resistant virus was found to be 10-fold less susceptible to 2'-fluorodGTP (Ki = 13.1 microM).

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

Priming of influenza mRNA transcription is inhibited in CHO cells treated with the methylation inhibitor, neplanocin A

Chinese hamster ovary cells were pretreated with Neplanocin A, a potent inhibitor of RNA methylation. Analysis of polyadenylated RNA from treated cells by high-pressure liquid chromatography revealed marked decreases of 2'-O-methylation within mRNA cap structures and of internal N6-methyladenosine residues. In these Neplanocin A-treated cells, influenza viral mRNA accumulation was virtually abolished. Cellular RNA from Neplanocin A-treated cells was substantially less efficient than RNA from control cells in priming cell-free influenza transcription reactions. These results suggest that the observed inhibition of influenza virus replication is due at least in part to impaired recognition of undermethylated cellular mRNA cap structures by the influenza polymerase complex.

Influenza virus gene expression: control mechanisms at early and late times of infection and nuclear-cytoplasmic transport of virus-specific RNAs

Single-stranded M13 DNAs specific for various influenza virus genomic segments were used to analyze the synthesis of virus-specific RNAs in infected cells. The results show that influenza virus infection is divided into two distinct phases. During the early phase, the syntheses of specific virion RNAs, viral mRNAs, and viral proteins were coupled. Thus, the NS (nonstructural) virion RNA was preferentially synthesized early, leading to the preferential synthesis of NS1 viral mRNA and NS1 protein; in contrast, M (matrix) RNA synthesis was delayed, leading to the delayed synthesis of M1 viral mRNA and M1 protein. This phase lasted for 2.5 h in BHK-21 cells, the time at which the rate of synthesis of all the viral mRNAs was maximal. During the second phase, the synthesis of all the virion RNAs remained at or near maximum until at least 5.5 h postinfection, whereas the rate of synthesis of all the viral mRNAs declined dramatically. By 4.5 h, the rate of synthesis of all the viral mRNAs was 5% of the maximum rate. Viral mRNA and protein syntheses were also not coupled, as the synthesis of all the viral proteins continued at maximum levels, indicating that protein synthesis during this phase was directed principally by previously synthesized viral mRNAs. Short pulses (3 min) with [3H]uridine and nonaqueous fractionation of cells were used to show that influenza virion RNA synthesis occurred in the nucleus, demonstrating that all virus-specific RNA synthesis was nuclear. Virion RNAs, like viral mRNAs, were efficiently transported to the cytoplasm at both early and late times of infection. In contrast, the full-length transcripts of the virion RNAs, which are the templates for virion RNA synthesis, were sequestered in the nucleus. Thus, the template RNAs, which were synthesized only at early times, remained in the nucleus to direct virion RNA synthesis throughout infection. These results enabled us to present an overall scheme for the control of influenza virus gene expression.

Inhibitory effect of diamidinophenylindole on the replication of influenza virus in permissive cellular hosts. Brief report

The production of avian and human strains of influenza virus was altered to various extents by treatment of various host cells with 40 micrograms/ml of diamidinophenylindole (DAPI). In infected LLC-MK 2 cells only an abortive replication cycle occurred; in other cell lines there was partial inhibition or no inhibition of replication. Virus polypeptide synthesis in LLC-MK 2 cells was confined to the early pattern of viral multiplication; only the P proteins, the nucleoprotein NP, and the non-structural protein NS 1 were synthesized. The stage of replication mainly affected by DAPI was between the fourth and the sixth hour after infection. The mode of action of the drug and its modulating effect on virus production is discussed.

Frog virus 3 requires RNA polymerase II for its replication

The involvement of host cell RNA polymerase II in the replication of frog virus 3 (FV 3) was examined in alpha-amanitin-sensitive or -resistant Chinese hamster ovary (CHO) cells in the presence and absence of alpha-amanitin. In the presence of alpha-amanitin, FV 3 replicated normally in resistant CHO cells but failed to do so in sensitive CHO cells. Synthesis of virus-specific RNAs and proteins was inhibited in sensitive cells infected in the presence of alpha-amanitin, but in alpha-amanitin-resistant cells, as expected, virus-specific protein synthesis and, by implication, virus-specific RNA synthesis were not affected by the presence of the drug. Inhibition of FV 3 replication was maximum when alpha-amanitin was added to sensitive CHO cells before virus adsorption, but the drug had no effect on virus replication if added after the adsorption. These data indicate that host RNA polymerase II was required for early transcription of the FV 3 genome and confirm a nuclear requirement for FV 3 RNA synthesis (R. Goorha et al., Virology 82:34-52, 1978).

Different patterns of replication in influenza virus-infected KB cells

When KB cells were infected either with the fowl plague (FPV) Rostock strain (Hav1N1) or the WSN (H0N1) strain of influenza A virus the yield of cell-associated haemagglutinin and neuraminidase polypeptides was essentially comparable, but virus particles were not produced in the FPV-KB system. WSN virus-infected KB cells synthesized normal amounts of mature virus particles and had all the characteristics of a permissive replication cycle. Biosynthesis and transport of RNP antigen from nucleus to cytoplasm of infected cells were traced by immunofluorescent staining at 4 and 8 hours after the beginning of infection. While the fluorescent-stained material was totally confined to the nuclei in FPV-infected KB cells, RNP antigen migrated out of the nucleus during the replicative cycle of WSN virus in the same host cell. Patterns of virus-specific protein synthesis were studied by pulse-labelling with 35S-methionine. The most significant feature concerned the amplification of synthesis of virus-induced matrix (M) protein which did not occur in FPV-infected cells but occurred normally during WSN infection. The different patterns of replication in the same host cell when infected by different influenza A viruses is discussed.

The coronavirus avian infectious bronchitis virus requires the cell nucleus and host transcriptional factors

Replication of avian infectious bronchitis virus in permissive BHK-21 cells is blocked when these cells are enucleated or irradiated with ultraviolet light prior to infection, or if cells are treated with α-amanitin during the virus growth cycle. This coronavirus, like influenza virus, can replicate normally in the presence of α-amanitin in Chinese hamster ovary cells which possess a drug-resistant RNA polymerase II. These findings indicate that avian infectious bronchitis virus requires the intact cell nucleus and one or more host transcriptional functions for productive infections. Preliminary data suggest that these cellular functions involve some aspect of virus-directed RNA synthesis.

Influenza B virus: alpha-amanitin sensitivity of replication and primer-dependence of in vitro transcription

The replication of influenza B/Lee/40 virus in MDCK (canine kidney) cells was sensitive to alpha-amanitin and actinomycin D. In vitro, virion transcriptase activity was stimulated by dinucleotide primers such as ApG. The above characteristics are shared by A/WSN virus.

Identification of the RNA region transferred from a representative primer, beta-globin mRNA, to influenza mRNA during in vitro transcription

Capped eukaryotic mRNAs strongly stimulate influenza viral RNA transcription in vitro and donate their cap and also additional nucleotides to the viral transcripts (1). To identify which bases of a given primer mRNA are transferred, we synthesized influenza viral mRNA using a primer rabbit globin mRNA (enriched in beta-globin mRNA) which had been labeled in vitro to high specific activity with 125I. We show that during transcription the same 125I-labeled oligonucleotides were transferred to the 5' termini of each of the eight viral mRNA segments. The predominant sequence, representing 75 percent of the transferred oligonucleotides, was identical to the first 13 nucleotides at the 5' end of beta-globin mRNA (m7G5'ppp5'm6AmC(m)ACUUGCUUUUG). Because only the C-residues are labeled with 125I, these results indicate that either the first 12, 13 or 14 5' terminal bases of beta-globin mRNA were transferred to the viral mRNAs. 125I-labeled oligonucleotides recovered from the viral mRNA in minor yields indicated that shorter 5' terminal pieces of beta-globin mRNA were sometimes transferred and that G was probably the first base inserted by transcription.

Inhibition of influenza C virus replication by actinomycin D, alpha-amanitin, and UV irradiation

Actinomycin D and alpha-amanitin caused similar reductions in the yields of influenza A/WSN and influenza C/JBH/1/66 viruses in a chicken kidney cell culture system. Irradiation of host cells with UV light before virus infection also produced a similar reduction in yields of the two viruses. The results indicate a close similarity between the replication processes of influenza C and other orthomyxoviruses.

Biogenesis of poxviruses: role for the DNA-dependent RNA polymerase II of the host during expression of late functions

The participation of host RNA polymerase II in the vaccinia life cycle was examined by comparing efficiency of multiplication after treating the Ama+ sensitive and Ama 102 drug resistant lines with alpha-amanitin. In the latter, resistance is due to a mutation in RNA polymerase II. The toxin profoundly reduces synthesis of virus-specified polypeptides and morphopoeisis in Ama+ but not in Ama 102 rat myoblasts without appreciably altering vaccinia DNA replication in either cell type. This implicates RNA polymerase II in the expression of late virus functions. Circumstantial evidence from a model system indicates that gamma irradiation of the host prior to infection might disrupt transcription into functional mRNA from the nucleus. Irradiation does not, however, alter the capability of the host to support vaccinia multiplication fully. Therefore, ongoing host nuclear transcription may not be required by this virus. The above results are consistent with the ability of cytoplasts to produce small quantities of mature progeny. Our studies lead us to hypothesize that RNA polymerase II or a subunit of the host enzyme may participate directly in late transcription of the vaccinia genome.

Transfer of 5'-terminal cap of globin mRNA to influenza viral complementary RNA during transcription in vitro

We have recently demonstrated that globin mRNAs are effective primers for influenza viral RNA transcription in vitro catalyzed by the virion transcriptase [Bouloy, M., Plotch, S. J. & Krug, R. M. (1978) Proc. Natl. Acad. Sci. USA 75, 4886-4890]. Here, we present direct evidence that the 5'-terminal methylated cap of the globin mRNAs is transferred to viral complementary RNA (cRNA) during transcription. Chemical (beta-elimination) or enzymatic removal of the cap of globin mRNAs eliminated essentially all their priming activity. Much of this activity could be restored by recapping the beta-eliminated globin mRNAs with the vaccinia virus guanylyl and methyl transferases. Globin mRNAs containing (32)P label only in the cap (m(7)G(32)pppm(6)A(m)-) were prepared by recapping beta-eliminated globin mRNAs with the vaccinia virus enzymes, [alpha-(32)P]GTP, and unlabeled S-adenosylmethionine. By using this labeled globin mRNA as primer and unlabeled nucleoside triphosphates as precursors, the viral cRNA segments that were synthesized were shown to contain a (32)P-labeled 5'-terminal cap structure. Gel electrophoretic analysis indicated that the globin mRNA-primed cRNA segments were 10-15 nucleotides longer at their 5' end than ApG-primed cRNA segments, which initiate exactly at the 3' end of the virion RNA templates. This suggests that, in addition to the cap, about 10-15 other nucleotides are also transferred from the globin mRNA to viral cRNA. A mechanism for the priming of influenza viral cRNA synthesis by globin mRNA is proposed.

Nuclear accumulation of influenza viral RNA transcripts and the effects of cycloheximide, actinomycin D, and alpha-amanitin

The use of virus-specific (32)P-labeled complementary DNA and (125)I-labeled virion RNA as hybridization probes has allowed us to quantitate the number of molecules of complementary RNA (cRNA) and progeny virion RNA in MDCK cells infected with influenza virus. We compared the distribution of cRNA between the nucleus and the cytoplasm in cycloheximide-treated cells to that found in untreated cells, beginning 1 h after infection. A greater percentage of the total cRNA was detected in the nucleus of the drug-treated cells at all times investigated. For the first 2 h after infection about 50% of the cRNA synthesized in the cycloheximide-treated cells was found in the nucleus. These nuclear cRNA molecules were characterized and shown to be polyadenylated transcripts of each of the genome virion RNA segments. Viral cRNA synthesis was not completely inhibited by the addition of actinomycin D at the beginning of infection, with or without the concomitant addition of cycloheximide. A large fraction (about 90%) of these cRNA sequences were detected in the nucleus. Characterization of these nuclear cRNA molecules showed that they contained polyadenylic acid and represented transcripts of both those segments coding for proteins synthesized predominantly early after infection ("early" proteins) and those virion RNA segments coding for "late" proteins. Also, in vitro translation of these cRNA molecules showed that they were functional virus mRNA's. In contrast to actinomycin D, alpha-amanitin completely inhibited cRNA synthesis when added at the beginning of infection, and addition of this drug after 1.5 h had no effect on further cRNA synthesis.

Amatoxins, phallotoxins, phallolysin, and antamanide: the biologically active components of poisonous Amanita mushrooms

This review gives a comprehensive account of the molecular toxicology of the bicyclic peptides obtained from the poisonous mushrooms of the genus Amanita. The discussion of the biochemical events will be preceded by a consideration of the chemistry of the toxic peptides. The structural features essential for biological activities of both the amatoxins and the phallotoxins will be discussed, also including the most important analytical data. Similar consideration will be given to antamanide, a cyclic peptide, which counteracts phalloidin. In addition, the phallolysins, three cytolytic proteins from Amanita phalloides will be discussed. The report on the biological activity of the amatoxins will deal with the sensitivity of the different RNA-polymerases towards the toxins and with their action on various cell types. Consideration will also be given to systems in which alpha-amanitin was used and can be used as a molecular tool; in the past, many investigators used the inhibitor in molecular biology, genetics, and even in physiological research. As for the phallotoxins, discussion of the affinity of these toxins for actin is provied. Further discussion attempts to understand the course of intoxication by filling in the gap between the first molecular event, formation of microfilaments, and the various lesions in hepatocytes during the intoxication.

Globin mRNAs are primers for the transcription of influenza viral RNA in vitro

Because influenza viral RNA transcription in vitro is greatly enhanced by the addition of a primer dinucleotide, ApG or GpG, we have proposed that viral RNA transcription in vivo requires initiation by primer RNAs synthesized by the host cell, specifically by RNA polymerase II, thereby explaining the alpha-amanitin sensitivity of viral RNA transcription in vivo. Here, we identify such primer RNAs, initially in reticulocyte extracts, where they are shown to be globin mRNAs. Purified globin mRNAs very effectively stimulated viral RNA transcription in vitro, and the resulting transcripts directed the synthesis of all the nonglycosylated virus-specific proteins in micrococcal nuclease-treated L cell extracts. The viral RNA transcripts synthesized in vitro primed by ApG also directed the synthesis of the nonglycosylated virus-specific proteins, but the globin mRNA-primed transcripts were translated about 3 times more efficiently. The translation of the globin mRNA-primed, but not the ApG-primed, viral RNA transcripts was inhibited by 7-methylguanosine 5'-phosphate in the presence of S-adenosylhomocysteine, suggesting that the globin mRNA-primed transcripts contained a 5'-terminal methylated cap structure. We propose that this cap was transferred from the globin mRNA primer to the newly synthesized viral RNA transcripts, because no detectable de novo synthesis of a methylated cap occurred during globin mRNA-primed viral RNA transcription. Preliminary experiments indicate that other purified eukaryotic mRNAs also stimulate influenza viral RNA transcription in vitro.