Nuclear-cytoplasmic transport and VAI RNA-independent translation of influenza viral messenger RNAs in late adenovirus-infected cells

Immune response during influenza virus infection among the population of Assam, Northeast India

Introduction

The pathogenicity of influenza virus infection is modulated by the cytokine expressions in patients. The present study was aimed to measure some important pro- and anti-inflammatory cytokines in influenza-infected population of Assam, Northeast India.

Materials and Methods

Influenza viruses consisting of subtypes influenza A(H1N1)pdm09, H3N2 and influenza-B were detected in patients with symptoms of influenza-like-illness by Real-time reverse transcriptase polymerase chain reaction (RT-PCR) method. Relative messenger ribonucleic acid (mRNA) quantification of four pro-inflammatory cytokines (interleukin [IL]-6, IL-8, interferon-gamma [IFN-γ] and tumour necrosis factor-alpha [TNF-α]) and one anti-inflammatory cytokine (IL-10) were measured in influenza-positive cases and non-influenza controls, by real-time RT-PCR. The plasma concentration of the cytokines was determined using cytometric-bead-array with flow cytometry.

Results

Influenza viruses were detected in 14.28% (50/350) of 350 patients screened. The expression of IL-6 was significantly raised in cases compared to controls (P = 0.018). IL-8 and IL-10 were also raised in cases, compared to controls (P = 0.284 and P = 0.018). An increased plasma TNF-α was observed in cases (1.36-fold and P = 0.289). The mRNA expression of IFN-γ was also increased in cases compared to controls (0.87-fold). However, the plasma level of IFN-γ was higher in the non-influenza controls compared to cases.

Conclusions

The study revealed a differential cytokine profile during influenza virus infection in the population, which may influence disease severity. An extended study on host immune response may provide better insights for the use of cytokine antagonists in therapeutic treatments among severe cases of influenza virus infection.

Comprehending a Killer: The Akt/mTOR Signaling Pathways Are Temporally High-Jacked by the Highly Pathogenic 1918 Influenza Virus

Previous transcriptomic analyses suggested that the 1918 influenza A virus (IAV1918), one of the most devastating pandemic viruses of the 20th century, induces a dysfunctional cytokine storm and affects other innate immune response patterns. Because all viruses are obligate parasites that require host cells for replication, we globally assessed how IAV1918 induces host protein dysregulation. We performed quantitative mass spectrometry of IAV1918-infected cells to measure host protein dysregulation. Selected proteins were validated by immunoblotting and phosphorylation levels of members of the PI3K/AKT/mTOR pathway were assessed. Compared to mock-infected controls, >170 proteins in the IAV1918-infected cells were dysregulated. Proteins mapped to amino sugar metabolism, purine metabolism, steroid biosynthesis, transmembrane receptors, phosphatases and transcription regulation. Immunoblotting demonstrated that IAV1918 induced a slight up-regulation of the lamin B receptor whereas all other tested virus strains induced a significant down-regulation. IAV1918 also strongly induced Rab5b expression whereas all other tested viruses induced minor up-regulation or down-regulation. IAV1918 showed early reduced phosphorylation of PI3K/AKT/mTOR pathway members and was especially sensitive to rapamycin. These results suggest the 1918 strain requires mTORC1 activity in early replication events, and may explain the unique pathogenicity of this virus.

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Proteomic analyses of influenza 1918 virus-infected cells identified >170 dysregulated host proteins.

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Dysregulated proteins mapped to numerous important cellular pathways.

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1918 virus infection showed prominent early reduced phosphorylation of PI3K/Akt/mTOR.

The 1918 influenza pandemic was one of the most devastating infectious disease events of the 20th century, resulting in 20–100 million deaths. Gene-based assays showed severe dysregulation of the host's cytokine responses, but little was known about global protein responses to virus infection. This work identifies unique and temporal alterations in phosphorylation of the PI3K/AKT/mTOR signaling pathway, which is important in determining cell death. This work paves the way for further research on how this pathway influences host mechanisms responsible for aiding virus replication and in determining levels and severity of influenza virus-induced patho

A comprehensive map of the influenza A virus replication cycle

Background

Influenza is a common infectious disease caused by influenza viruses. Annual epidemics cause severe illnesses, deaths, and economic loss around the world. To better defend against influenza viral infection, it is essential to understand its mechanisms and associated host responses. Many studies have been conducted to elucidate these mechanisms, however, the overall picture remains incompletely understood. A systematic understanding of influenza viral infection in host cells is needed to facilitate the identification of influential host response mechanisms and potential drug targets.

Description

We constructed a comprehensive map of the influenza A virus (‘IAV’) life cycle (‘FluMap’) by undertaking a literature-based, manual curation approach. Based on information obtained from publicly available pathway databases, updated with literature-based information and input from expert virologists and immunologists, FluMap is currently composed of 960 factors (i.e., proteins, mRNAs etc.) and 456 reactions, and is annotated with ~500 papers and curation comments. In addition to detailing the type of molecular interactions, isolate/strain specific data are also available. The FluMap was built with the pathway editor CellDesigner in standard SBML (Systems Biology Markup Language) format and visualized as an SBGN (Systems Biology Graphical Notation) diagram. It is also available as a web service (online map) based on the iPathways+ system to enable community discussion by influenza researchers. We also demonstrate computational network analyses to identify targets using the FluMap.

Conclusion

The FluMap is a comprehensive pathway map that can serve as a graphically presented knowledge-base and as a platform to analyze functional interactions between IAV and host factors. Publicly available webtools will allow continuous updating to ensure the most reliable representation of the host-virus interaction network. The FluMap is available at http://www.influenza-x.org/flumap/.

Influenza virus polymerase confers independence of the cellular cap-binding factor eIF4E for viral mRNA translation

The influenza virus mRNAs are structurally similar to cellular mRNAs nevertheless; the virus promotes selective translation of viral mRNAs despite the inhibition of host cell protein synthesis. The infection proceeds normally upon functional impairment of eIF4E cap-binding protein, but requires functional eIF4A helicase and eIF4G factor. Here, we have studied whether the presence of cis elements in viral mRNAs or the action of viral proteins is responsible for this eIF4E-independence. The eIF4E protein is required for viral mRNA translation in vitro, indicating that cis-acting RNA sequences are not involved in this process. We also show that PB2 viral polymerase subunit interacts with the eIF4G protein. In addition, a chimeric mRNA containing viral UTR sequences transcribed by the viral polymerase out of the infection is successfully translated independently of an impaired eIF4E factor. These data support that the viral polymerase is responsible for the eIF4E independence of influenza virus mRNA translation.

So similar, yet so different: selective translation of capped and polyadenylated viral mRNAs in the influenza virus infected cell

Influenza virus is included among the Orthomyxoviridae family and it is a major public health problem causing annual mortality worldwide. Viral mRNAs bear short capped oligonucleotide sequences at their 5'-ends, acquired from host cell pre-mRNAs during viral transcription, and are polyadenylated at their 3'-end. Therefore, viral and cellular mRNAs are undistinguishable from a structural point of view. However, selective translation of viral proteins occurs upon infection, while initiation and elongation steps of cellular mRNA translation are efficiently inhibited. Viruses do not possess the complex machinery required to translate their mRNAs and are then obliged to compete for host-cell factors and manipulate the translation apparatus to their own benefit. Thus, the understanding of the processes that govern viral translation could facilitate the finding of possible targets for anti viral interventions. In the present review, we will point out the mechanisms by which influenza virus takes control of the host-cell protein synthesis machinery to ensure the production of new viral particles. First, we will discuss the mechanisms by which the virus counteracts the anti viral translation repression induced in the infected cell. Next, we will focus on the shut-off of cellular protein synthesis and the specific requirements for the eIF4F complex on influenza mRNA translation. Finally, we will discuss the role of different cellular and viral proteins in the selective translation of viral messengers in the infected cell and we will summarize the proposed mechanisms for the recruitment of cellular translational machinery to the viral mRNAs.

Influenza virus mRNA translation revisited: is the eIF4E cap-binding factor required for viral mRNA translation?

Influenza virus mRNAs bear a short capped oligonucleotide sequence at their 5' ends derived from the host cell pre-mRNAs by a "cap-snatching" mechanism, followed immediately by a common viral sequence. At their 3' ends, they contain a poly(A) tail. Although cellular and viral mRNAs are structurally similar, influenza virus promotes the selective translation of its mRNAs despite the inhibition of host cell protein synthesis. The viral polymerase performs the cap snatching and binds selectively to the 5' common viral sequence. As viral mRNAs are recognized by their own cap-binding complex, we tested whether viral mRNA translation occurs without the contribution of the eIF4E protein, the cellular factor required for cap-dependent translation. Here, we show that influenza virus infection proceeds normally in different situations of functional impairment of the eIF4E factor. In addition, influenza virus polymerase binds to translation preinitiation complexes, and furthermore, under conditions of decreased eIF4GI association to cap structures, an increase in eIF4GI binding to these structures was found upon influenza virus infection. This is the first report providing evidence that influenza virus mRNA translation proceeds independently of a fully active translation initiation factor (eIF4E). The data reported are in agreement with a role of viral polymerase as a substitute for the eIF4E factor for viral mRNA translation.

Defective RNA replication and late gene expression in temperature-sensitive influenza viruses expressing deleted forms of the NS1 protein

Influenza A virus mutants expressing C-terminally deleted forms of the NS1 protein (NS1-81 and NS1-110) were generated by plasmid rescue. These viruses were temperature sensitive and showed a small plaque size at the permissive temperature. The accumulation of virion RNA in mutant virus-infected cells was reduced at the restrictive temperature, while the accumulation of cRNA or mRNA was not affected, indicating that the NS1 protein is involved in the control of transcription versus replication processes in the infection. The synthesis and accumulation of late virus proteins were reduced in NS1-81 mutant-infected cells at the permissive temperature and were essentially abolished for both viruses at the restrictive temperature, while synthesis and accumulation of nucleoprotein (NP) were unaffected. Probably as a consequence, the nucleocytoplasmic export of virus NP was strongly inhibited at the restrictive temperature. These results indicate that the NS1 protein is essential for nuclear and cytoplasmic steps during the virus cycle.

Interferon, PKR, virology, and genomics: what is past and what is next in the new millennium?

This paper provides an opportunity to reflect on my work in the interferon and cytokine field for the past almost 20 years and to look forward to the future. Winning the Milstein Award in 1999 was a great thrill. I briefly trace the history of my career from New York City to Seattle, leading up to the Paris award, and then look forward to the future that is full of promise because of the near-infinite power of genomics, computers, and other new technologies.

Translational control of viral gene expression in eukaryotes

As obligate intracellular parasites, viruses rely exclusively on the translational machinery of the host cell for the synthesis of viral proteins. This relationship has imposed numerous challenges on both the infecting virus and the host cell. Importantly, viruses must compete with the endogenous transcripts of the host cell for the translation of viral mRNA. Eukaryotic viruses have thus evolved diverse mechanisms to ensure translational efficiency of viral mRNA above and beyond that of cellular mRNA. Mechanisms that facilitate the efficient and selective translation of viral mRNA may be inherent in the structure of the viral nucleic acid itself and can involve the recruitment and/or modification of specific host factors. These processes serve to redirect the translation apparatus to favor viral transcripts, and they often come at the expense of the host cell. Accordingly, eukaryotic cells have developed antiviral countermeasures to target the translational machinery and disrupt protein synthesis during the course of virus infection. Not to be outdone, many viruses have answered these countermeasures with their own mechanisms to disrupt cellular antiviral pathways, thereby ensuring the uncompromised translation of virion proteins. Here we review the varied and complex translational programs employed by eukaryotic viruses. We discuss how these translational strategies have been incorporated into the virus life cycle and examine how such programming contributes to the pathogenesis of the host cell.

Regulation of eukaryotic protein synthesis: selective influenza viral mRNA translation is mediated by the cellular RNA-binding protein GRSF-1

To better understand regulation of eukaryotic protein synthesis, we studied cellular and viral mRNA translation in influenza virus-infected cells. Influenza virus infection results in a dramatic shut-off of cellular protein synthesis that is concomitant with selective viral mRNA translation. Earlier work showed that these events are mediated by viral and/or cellular factors binding to the 5' untranslated region (5' UTR) of viral mRNAs. To identify trans-acting cellular proteins responsible for selective viral protein synthesis, we employed the yeast three-hybrid system. Using the 5' UTR of the influenza virus nucleocapsid protein (NP) mRNA as bait, we identified the cellular RNA-recognition motif containing RNA-binding protein G-rich sequence factor 1 (GRSF-1) as a positive-acting translational regulatory factor. The in vivo yeast assay revealed GRSF-1 specifically bound to the NP 5' UTR but not select NP 5' UTR mutants or cellular RNA 5' UTRs. These data were confirmed by gel shift assays using recombinant GRSF-1. Importantly, recombinant GRSF-1 specifically stimulated translation of a NP 5' UTR-driven template in cell-free translation systems. Furthermore, translation efficiency of NP 5' UTR-driven templates was reduced markedly in GRSF-1-depleted HeLa cell extracts, but restored in GRSF-1-reconstituted extracts. GRSF-1 also stimulated translation of an NP 5' UTR-driven template in HeLa cell extracts that were depleted of essential factors by addition of RNA oligonucleotides representing the viral 5' UTR RNA. Taken together, these data document the functional demonstration of a cellular protein binding to influenza virus RNAs and, importantly, suggest that influenza virus may recruit GRSF-1 to the 5' UTR to ensure preferential translation of viral mRNAs in infected cells.

The N-terminal half of the influenza virus NS1 protein is sufficient for nuclear retention of mRNA and enhancement of viral mRNA translation

A collection of C-terminal deletion mutants of the influenza A virus NS1 gene has been used to define the regions of the NS1 protein involved in its functionality. Immunofluorescence analyses showed that the NS1 protein sequences downstream from position 81 are not required for nuclear transport. The capacity of these mutants to bind RNA was studied by in vitro binding tests using a model vRNA probe. These experiments showed that the N-terminal 81 amino acids of NS1 protein are sufficient for RNA binding activity. The collection of mutants also served to map the NS1 sequences required for nuclear retention of mRNA and for stimulation of viral mRNA translation, using the NP gene as reporter. The results obtained indicated that the N-terminal 113 amino acids of NS1 protein are sufficient for nuclear retention of mRNA and stimulation of viral mRNA translation. The possibility that this region of the protein may be sufficient for virus viability is discussed in relation to the sequences of NS1 genes of field isolates and to the phenotype of known viral mutants affected in the NS1 gene.

mRNA export correlates with activation of transcription in human subgroup C adenovirus-infected cells

To investigate the mechanisms by which viral mRNA species are distinguished from their cellular counterparts for export to the cytoplasm during the late phase of subgroup C adenovirus infection, we have examined the metabolism of several cellular and viral mRNAs in human cells productively infected by adenovirus type 5 (Ad5). Several cellular mRNAs that were refractory to, or could escape from, adenovirus-induced inhibition of export of mRNA from the nucleus have been identified. This group includes Hsp70 mRNAs synthesized upon heat shock of Ad5-infected 293 or HeLa cells during the late phase of infection. However, successful export in Ad5-infected cells is not a specific response to heat shock, for beta-tubulin and interferon-inducible mRNAs were also refractory to virus-induced export inhibition. The export of these cellular mRNAs, like that of viral late mRNAs, required the E1B 55-kDa protein. Export to the cytoplasm during the late phase of Ad5 infection of several cellular mRNAs, including members of the Hsp70 family whose export was inhibited under some, but not other, conditions, indicates that viral mRNA species cannot be selectively exported by virtue of specific sequence or structural features. Cellular and viral late mRNAs that can be exported from the nucleus to the cytoplasm were expressed from genes whose transcription was induced or activated during the late phase of Ad5 infection. Consistent with the possibility that successful export is governed by transcriptional activation in the late phase of adenovirus infection, newly synthesized viral early E1A mRNA was subject to export inhibition during the late phase of infection.

Intracellular structure and nucleocytoplasmic transport

Intracellular movement of any solute or particle accords with one of two general schemes: either it takes place predominantly in the solution phase or it occurs by dynamic interactions with solid-state structures. If nucleocytoplasmic exchanges of macromolecules and complexes are predominantly solution-phase processes, i.e., if the former ("diffusionist") perspective applies, then the only significant structures in nucleocytoplasmic transport are the pore complexes. However, if such exchanges accord with the latter ("solid-state") perspective, then the roles of the nucleoskeleton and cytoskeleton in nucleocytoplasmic transport are potentially, at least, as important as that of the pore complexes. The role of the nucleoskeleton in mRNA transport is more difficult to evaluate than that of the cytoskeleton because it is less well characterized, and current evidence does not exclude either perspective. However, the balance of evidence favors a solid-state scheme. It is argued that ribosomal subunits are also more likely to migrate by a solid-state rather than a diffusionist mechanism, though the opposite is true of proteins and tRNAs. Moreover, recent data on the effects of viral proteins on intranuclear RNA processing and migration accord with the solid-state perspective. In view of this balance of evidence, three possible solid-state mechanisms for nucleocytoplasmic mRNA transport are described and evaluated. The explanatory advantage of solid-state models is contrasted with the heuristic advantage of diffusion theory, but it is argued that diffusion theory itself, even aided by modern computational techniques and numerical and graphical approaches, cannot account for data describing the movements of materials within the cell. Therefore, the mechanisms envisaged in a diffusionist perspective cannot be confined to diffusion alone, but must include other processes such as bulk fluid flow.

Adenoviral E1B-55kDa protein inhibits yeast mRNA export and perturbs nuclear structure

The mechanisms of export of RNA from the nucleus are poorly understood; however, several viral proteins modulate nucleocytoplasmic transport of mRNA. Among these are the adenoviral proteins E1B-55kDa and E4-34kDa. Late in infection, these proteins inhibit export of host transcripts and promote export of viral mRNA. To investigate the mechanism by which these proteins act, we have expressed them in Saccharomyces cerevisiae. Overexpression of either or both proteins has no obvious effect on cell growth. By contrast, overexpression of E1B-55kDa bearing a nuclear localization signal (NLS) dramatically inhibits cell growth. In this situation, the NLS-E1B-55kDa protein is localized to the nuclear periphery, fibrous material is seen in the nucleoplasm, and poly(A)+ RNA accumulates in the nucleus. Simultaneous overexpression of E4-34kDa bearing or lacking an NLS does not modify these effects. We discuss the mechanisms of selective mRNA transport.

Influenza virus NS1 protein enhances the rate of translation initiation of viral mRNAs

The effect of NS1 protein on the efficiency of influenza virus mRNA translation was evaluated by determining the accumulation of nucleoprotein (NP) or M1 mRNAs in the cytoplasm of cells expressing either of these genes alone or in combination with the NS1 gene, as well as the total cell accumulation of NP or M1 protein. Coexpression of NS1, but not of NS2 protein, led to increases in the translation of these mRNAs in the range of 5- to 100-fold. This translation enhancement was specific for viral mRNAs, since the translation of neither cat nor lacZ mRNAs was affected by the coexpression of NS1 protein. The use of chimeric cat genes containing the 5'-extracistronic sequences of the influenza virus mRNAs corresponding to segment 2, 7, or 8 indicated that these sequences can in part account for the observed effect. The enhancement of viral mRNA translation mediated by NS1 protein was due to an increase in the translation initiation rate, since the sizes of NP-specific polysomes, but not those of lacZ-specific polysomes, was significantly higher in cells coexpressing NS1 protein than in those expressing only the NP gene.

The regulation of export of mRNA from nucleus to cytoplasm

The past year has been marked by the discovery that the influenza virus NS1 protein belongs to the group of viral proteins that regulate the nuclear export of mRNA. This protein, like other viral proteins in this group, such as the Rev protein of human immunodeficiency virus 1 (HIV-1) and the complex of two adenovirus early proteins, has the potential to provide insights into the poorly understood process of the nuclear export of mRNA.

Modification of eukaryotic initiation factor 4F during infection by influenza virus

Influenza virus infection of cells is accompanied by a striking shutoff of cellular protein synthesis, resulting in the exclusive translation of viral mRNAs. The mechanism for control of cellular protein synthesis by influenza virus is poorly understood, but several translation properties of influenza virus mRNAs which are potentially involved have been described. Influenza virus mRNAs possess the surprising ability to translate in the presence of inhibitory levels of inactive (phosphorylated) eukaryotic initiation factor 2 (eIF-2). In addition, influenza virus mRNAs were shown to be capable of translating in cells during the late phase of adenovirus infection but not in cells infected by poliovirus. Since both adenovirus and poliovirus facilitate virus-specific translation by impairing the activity of initiation factor eIF-4F (cap-binding protein complex) but through different mechanisms, we investigated the translation properties of influenza virus mRNAs in more detail. We show that influenza virus infection is associated with the significant dephosphorylation and inactivation of eIF-4E (cap-binding protein), a component of eIF-4F, and accordingly that influenza virus mRNAs possess a moderate ability to translate by using low levels of eIF-4F. We also confirm the ability of influenza virus mRNAs to translate in the presence of high levels of inactive (phosphorylated) eIF-2 but to a more limited extent than reported previously. We suggest a potential mechanism for the regulation of protein synthesis by influenza virus involving a decreased requirement for large pools of active eIF-4F and eIF-2.

Translational regulation by the interferon-induced double-stranded-RNA-activated 68-kDa protein kinase

Activation of the interferon-inducible 68-kDa protein kinase (referred to as P68) by double-stranded RNA catalyzes phosphorylation of the alpha subunit of eukaryotic protein synthesis initiation factor 2. We have analyzed the transient expression of mutant and wild-type kinase molecules in transfected COS cells to examine the effects of the kinase on gene expression in the absence of other interferon-induced gene products. The wild-type P68 kinase was expressed inefficiently whereas a catalytically inactive P68 was expressed at 30- to 40-fold higher levels. Protein stability measurements and primer-extension analysis of human kinase-specific mRNA levels provided evidence that kinase expression was regulated at the level of mRNA translation. Further, cotransfection experiments revealed that the domain II catalytically inactive mutant could stimulate reporter gene protein synthesis in a transdominant manner. We also examined the expression of mutants with deletions in the N-terminal double-stranded RNA binding domains and found that a kinase construct lacking aa 156-243 was expressed at levels comparable to the wild type whereas a P68 construct lacking aa 91-243 was expressed at levels 70-fold higher. Both the inactive domain II P68 mutant and the deletion mutant lacking aa 91-243 were less inhibitory to growth in yeast due to the reduced ability to phosphorylate initiation factor 2 alpha in vivo. In conclusion we have demonstrated that the P68 kinase can regulate mRNA translation primarily of its own mRNA and to a lesser extent of a heterologous mRNA and that this regulation is notably affected by mutations in either the catalytic or N-terminal regulatory domains.

Inhibitory effects of vesicular stomatitis virus on cellular and influenza viral RNA metabolism and protein synthesis

Infection with vesicular stomatitis virus (VSV) results in the rapid inhibition of cellular macromolecular synthesis, including transcription, translation, and maturation of the U1 and U2 snRNPs. Unlike infection with VSV, influenza virus infection did not result in the inhibition of either the processing of U1 and U2 snRNAs or the assembly of the RNPs. Although influenza virus relies on the cellular splicing apparatus to generate viral mRNAs, the maturation of snRNPs was inhibited during double infections with VSV. However, this inhibition of snRNP maturation had no effect on the splicing of a cellular pre mRNA in extracts prepared from VSV-infected HeLa cells. Thus, the effects of VSV on the processing and assembly of snRNPs appear to involve virus-specific functions and unique cellular targets. Coinfection with VSV and influenza virus resulted in the dramatic inhibition of influenza virus transcription; polyadenylated mRNAs corresponding to the influenza virus NP and NS1 proteins could not be detected by Northern blot analysis. However, reduced levels of the influenza virus replicative templates were still synthesized during double infection. Coinfection with VSV also resulted in the inhibition of influenza viral mRNA translation, even when superinfection with VSV was delayed until 3 or 6 hr after influenza virus infection. VSV required at least 2 hr to affect the inhibition of translation; this corresponded to the time after VSV infection when inhibition of cellular protein synthesis was evident. These results demonstrate that, in contrast to adenovirus, the VSV-mediated inhibition of cellular macromolecular synthesis may be effective against influenza virus.

The cellular 68,000-Mr protein kinase is highly autophosphorylated and activated yet significantly degraded during poliovirus infection: implications for translational regulation

We investigated the possible translational regulatory roles played by the interferon-induced, double-stranded-RNA-activated protein kinase (P68) and its natural substrate, eucaryotic initiation factor 2 (eIF-2), in poliovirus-infected cells. We demonstrated that protein kinase P68 was both highly autophosphorylated and activated during poliovirus infection. In accordance with these results, immunoprecipitation analysis revealed that phosphorylation of the endogenous eIF-2 alpha subunit also increased in poliovirus-infected cells. We found that double-stranded RNA synthesized during infection likely induced the high levels of P68 autophosphorylation. To determine whether the increase in kinase activity also could be attributed to induction of P68 synthesis, physical levels of protein kinase were measured. It was unexpectedly found that P68 protein levels did not increase but rather dramatically declined in poliovirus-infected cells. Pulse-chase experiments confirmed that the protein kinase was significantly degraded during virus infection. We corroborated our in vivo observations by developing an in vitro assay for P68 degradation using cell extracts. The possible consequences of P68 degradation and increased eIF-2 alpha phosphorylation for protein synthesis regulation in poliovirus-infected cells are discussed.

Effect of mutations and deletions in a bicistronic mRNA on the synthesis of influenza B virus NB and NA glycoproteins

The mRNA derived from influenza B virus RNA segment 6 is functionally bicistronic and encodes the NB and NA glycoproteins in different, overlapping reading frames. NB protein synthesis is initiated at the 5'-proximal AUG codon, and 4 nucleotides downstream there is a second AUG codon which is used to initiate NA protein synthesis. The nucleotide sequence context of the first AUG codon conforms closely with the established 5'-CC(A/G)CCAUGG-3' consensus sequence (M. Kozak, Nucleic Acids Res. 15:8125-8148, 1987), which should favor initiation of NB protein synthesis at this site, yet NB and NA are found to accumulate in approximately equal amounts in infected cells. To determine the features important for allowing initiation at the second 5'-proximal AUG codon, we made changes in the 5'-terminal region of the mRNA, including deletions, insertions, and site-specific mutations. The recombinant DNA molecules were expressed in eucaryotic cells, and the accumulation of NB and NA was quantitated. The data indicate that changes in the immediate sequence around the first AUG codon do not make a large difference in the amounts of NB and NA that accumulate, but that when the first AUG codon is displaced from its normal position it is now quite efficient at preventing downstream initiation events. In addition, the data indicate that an element of the B/NB/NA mRNA 5' untranslated leader region acts in cis to enhance the expression of NB and NA.

Adenoviruses as vectors for the transfer of genetic information and for the construction of new type vaccines

At present many types of corpuscular nondefective, conditional-defective and helper-dependent expressing adenoviral vectors are available which can be used in constructing gene-engineered live or inactivated viral vaccines. In particular, promising results have been obtained with live recombinant human adenoviruses expressing the S antigen of hepatitis B virus, capsid protein of rotaviruses and gB protein of herpes virus. These recombinants are proper candidates for testing as corresponding vaccine strains, a good alternative to well-known recombinant vaccine virus.

Translational regulation of influenza virus mRNAs

cDNAs for genome RNAs of influenza virus A/PR/8/34 were cloned, and portions containing the ATG for initiation codon of translation were inserted into the 5' leader sequence of the chloramphenicol acetyltransferase (CAT) gene in a pSV2cat vector. When transfected cells were super-infected with influenza virus, the CAT activity was found to vary in a time-dependent fashion: A construct containing a cDNA segment for the nonstructural (NS) protein directed the highest activity during the early stage of infection, while a construct containing a cDNA segment for the neuraminidase (NA) directed the highest activity during the late stage of infection. This time-dependent variation in the CAT activity is in good agreement with that of the synthesis rate of respective viral proteins in infected cells. We propose that the translational efficiency of viral mRNA is subjected to temporal control following viral infection, although viral protein synthesis itself is regulated primarily at the level of mRNA synthesis.

Influenza virus RNA replication in vitro: synthesis of viral template RNAs and virion RNAs in the absence of an added primer

The two steps in influenza virus RNA replication are (i) the synthesis of template RNAs, i.e., full-length copies of the virion RNAs, and (ii) the copying of these template RNAs into new virion RNAs. We prepared nuclear extracts from infected HeLa cells that catalyzed both template RNA and virion RNA synthesis in vitro in the absence of an added primer. Antibody depletion experiments implicated nucleocapsid protein molecules not associated with nucleocapsids in template RNA synthesis for antitermination at the polyadenylation site used during viral mRNA synthesis. Experiments with the WSN influenza virus temperature-sensitive mutant ts56 containing a defect in the nucleocapsid protein proved that the nucleocapsid protein was indeed required for template RNA synthesis both in vivo and in vitro. Nuclear extracts prepared from mutant virus-infected cells synthesized template RNA at the permissive temperature but not at the nonpermissive temperature, whereas the synthesis of mRNA-size transcripts was not decreased at the nonpermissive temperature. Antibody depletion experiments showed that nucleocapsid protein molecules not associated with nucleocapsids were also required for the copying of template RNA into virion RNA. In contrast to the situation with the synthesis of transcripts complementary to virion RNA, no discrete termination product(s) were made during virion RNA synthesis in vitro in the absence of nucleocapsid protein molecules.

Efficient transcription, not translation, is dependent on adenovirus tripartite leader sequences at late times of infection

To determine whether the tripartite leader is required for efficient translation in adenovirus-infected cells at late times of infection, we constructed recombinant adenoviruses containing the influenza virus nucleocapsid protein (NP) gene expressed under the control of the adenovirus major late promoter (MLP). We chose the NP gene because previous results showed that the influenza virus NP mRNA was an extremely effective initiator of translation in cells which were superinfected with influenza virus at late times of adenovirus infection (M. G. Katze, B. M. Detjen, B. Safer, and R. M. Krug, Mol. Cell. Biol. 6:1741-1750, 1986). The NP gene in the adenovirus recombinants was inserted downstream of an MLP that replaced part of the early (E1A) region. The resulting NP mRNAs either lacked any tripartite leader sequences or contained at their 5' ends various portions of the tripartite leader: 33, 172, or all 200 nucleotides of the leader. The relative amounts of the NP protein synthesized by the recombinants were directly proportional to the amounts of the NP mRNA made, indicating that the presence of 5' tripartite leader sequences did not enhance the translation of NP mRNA. In addition, the sizes of the polysomes containing NP mRNA were not increased by the presence of tripartite leader sequences, indicating that the initiation of translation was not enhanced by these sequences. On the other hand, the presence of tripartite leader sequences immediately downstream of the MLP did enhance the transcription of the inserted NP gene, as shown by Northern (RNA) analysis of in vivo NP mRNA levels and by in vitro runoff assays with isolated nuclei. Our results indicate that more than 33 nucleotides of the first leader segment of the tripartite leader are required for optimal transcription from the MLP.

Concomitant transcriptional and post-transcriptional control of mRNA abundance during human myeloid cell differentiation

The mechanisms controlling the expression of two genes during the differentiation of HL60 cells have been studied. The relative abundance of one mRNA, designated 2B5, increases during retinoic acid-induced differentiation; this increase can be accounted for, in part at least, by a marked increase in the rate of transcription of the gene. The relative abundance of the second, pCG56, decreases during retinoic acid-induced differentiation although the rate of transcription of this gene also increases during the course of differentiation. The bulk of pCG56 transcripts, though polyadenylated and apparently fully processed, are located in the nuclei of the uninduced cells, but on the polysomes of the induced cells. The data indicate that the change in the expression of the gene encoding pCG56 RNA is regulated differently from that encoding 2B5 RNA, and are interpreted as evidence that the pCG56 gene is regulated by an interaction between transcriptional and post-transcriptional controls. Furthermore, the latter includes both mRNA stability and a post-transcriptional mechanism that has not previously been demonstrated in differentiating cells, viz. nucleo-cytoplasmic transport of mRNA.

Adenovirus VAI RNA complexes with the 68 000 Mr protein kinase to regulate its autophosphorylation and activity

We have investigated the interaction of VAI RNA with the interferon-induced, double-stranded (ds) RNA-activated protein kinase, P68, both of which regulate protein synthesis in adenovirus-infected cells. Previous work has shown that during infection by the VAI RNA-negative mutant, dl331, both viral and cellular protein synthesis are inhibited due to phosphorylation of the alpha-subunit of the eukaryotic initiation factor, eIF-2, by the P68 protein kinase. Utilizing monoclonal antibodies specific for P68, we demonstrated that the physical levels of P68 in dl331-infected, wild-type Ad2-infected and uninfected cells were all comparable suggesting that the elevated kinase activity detected during mutant infection was not due to increased P68 synthesis. To examine the basis of the increased activity of P68, the protein kinase was purified from infected-cell extracts using the monoclonal antibody. We found that P68 was heavily autophosphorylated during dl331 infection but not during wild-type or mock infection. The extent of autophosphorylation correlated with elevated P68 activity and the loss of the dsRNA requirements to phosphorylate the exogenous substrates, eIF-1 alpha and histones. We also analyzed VAI RNA function in vitro and present evidence that purified VAI RNA can block the autophosphorylation of P68 in the ribosomal salt wash fraction of interferon-treated cells. Finally we suggest VAI RNA functions through a direct interaction with the P68 protein kinase, since we demonstrated that VAI RNA forms a complex with P68 both in vitro and in vivo.

Translational control by influenza virus: suppression of the kinase that phosphorylates the alpha subunit of initiation factor eIF-2 and selective translation of influenza viral mRNAs

Selective translation of influenza viral mRNAs occurs after influenza virus superinfection of cells infected with the VAI RNA-negative adenovirus mutant dl331 (M. G. Katze, Y.-T. Chen, and R. M. Krug, Cell 37:483-490, 1984). Cell extracts from these doubly infected cells catalyze the initiation of essentially only influenza viral protein synthesis, reproducing the in vivo situation. This selective translation is correlated with a 5- to 10-fold suppression of the dl331-induced kinase that phosphorylates the alpha subunit of eucaryotic initiation factor eIF-2. This strongly suggests that influenza virus encodes a gene product that, analogous to the adenoviral VAI RNA, prevents the shutdown of overall protein synthesis caused by an eIF-2 alpha kinase turned on by viral infection. Adenoviral mRNA translation was restored to the extract from the doubly infected cells by the addition of the guanine nucleotide exchange factor eIF-2B, which is responsible for the normal recycling of eIF-2 during protein synthesis. This indicates that the residual kinase in the doubly infected cells leads to a limitation in functional (nonsequestered) eIF-2B and hence functional (GTP-containing) eIF-2 and that under these conditions influenza viral mRNAs are selectively translated over adenoviral mRNAs. Addition of double-stranded RNA to the extracts from these cells restored the eIF-2 alpha kinase to a level approaching that seen in extracts from cells infected with dl331 alone and caused the inhibition of influenza viral mRNA translation. This suggests that the putative influenza viral gene product acts against the double-stranded RNA activation of the kinase and indicates that influenza viral mRNA translation is also linked to the level of functional eIF-2. Our results thus indicate that a limitation in functional eIF-2 which causes a nonspecific reduction in the rate of initiation of protein synthesis results in the preferential translation of the better mRNAs (influenza viral mRNAs) at the expense of the poorer mRNAs (adenoviral mRNAs).

5'-terminal sequences influence the segregation of ground squirrel hepatitis virus RNAs into polyribosomes and viral core particles

To determine which of the major ground squirrel hepatitis virus RNAs serve as mRNAs and which serve as templates for reverse transcription of the genome, we analyzed the subcellular distribution of these RNAs in livers of infected ground squirrels. Both major classes of viral RNA, the 2.3- and 3.5-kilobase (kb) classes, are unspliced, are polyadenylated at a common position, and display heterogeneous 5' ends that can encode proteins with different amino termini (G.H. Enders, D. Ganem, and H. Varmus, Cell 42:297-308, 1985). Both of the 2.3-kb RNAs, which encode surface antigens, appear to be predominantly associated with polyribosomes. Of the three 3.5-kb RNAs, the two longer, which can encode a protein initiated from the first methionine codon in the core antigen gene, appear to be predominantly associated with polyribosomes, and a minority of the shortest 3.5-kb RNAs, which can encode a protein initiated from the second methionine in the core antigen gene, appears to be associated with polyribosomes. This last RNA is instead found predominantly within viral core particles, consistent with evidence that indirectly implicates it in two steps of viral DNA synthesis (C. Seeger, D. Ganem, and H.E. Varmus, Science 232:477-484, 1986). None of the other viral RNAs is detectably packaged into cores. These findings provide independent evidence that the shortest 3.5-kb RNA is the template for synthesis of the viral genome and reveal a novel selectivity in viral RNA packaging.

Cellular mRNA translation is blocked at both initiation and elongation after infection by influenza virus or adenovirus

During influenza virus infection, protein synthesis is maintained at high levels and a dramatic switch from cellular to viral protein synthesis occurs despite the presence of high levels of functional cellular mRNAs in the cytoplasm of infected cells (M. G. Katze and R. M. Krug, Mol. Cell. Biol. 4:2198-2206, 1984). To determine the step at which the block in cellular mRNA translation occurs, we compared the polysome association of several representative cellular mRNAs (actin, glyceraldehyde-3-phosphate dehydrogenase, and pHe7 mRNAs) in infected and uninfected HeLa cells. We showed that most of these cellular mRNAs remained polysome associated after influenza viral infection, indicating that the elongation of the proteins encoded by these cellular mRNAs was severely inhibited. Because the polysomes containing these cellular mRNAs did not increase in size but either remained the same size or decreased in size, the initiation step in cellular protein synthesis must also have been defective. Several control experiments established that the cellular mRNAs sedimenting in the polysome region of sucrose gradients were in fact associated with polyribosomes. Most definitively, puromycin treatment of infected cells caused the dissociation of polysomes and the release of cellular, as well as viral, mRNAs from the polysomes, indicating that the cellular mRNAs were associated with polysomes that were capable of forming at least a single peptide bond. A similar analysis was performed with HeLa cells infected by adenovirus, which also dramatically shuts down cellular protein synthesis. Again, it was found that most of the cellular mRNAs, which were translatable in reticulocyte extracts, remained associated with polysomes and that there was a combined initiation-elongation block to cellular protein synthesis. In cells infected by both adenovirus and influenza virus, influenza viral mRNAs were on larger polysomes than were several late adenoviral mRNAs with comparably sized coding regions. In addition, after influenza virus superinfection of cells infected by the adenovirus mutant dl331, a situation in which there is a limitation in the amount of functional initiation factor eIF-2 (M. G. Katze, B. M. Detjen, B. Safer, and R. M. Krug, Mol. Cell. Biol. 6:1741-1750, 1986), influenza viral mRNAs, but not late adenoviral mRNAs, were on polysomes. These results indicate that influenza viral mRNAs are better initiators of translation than are late adenoviral mRNAs.

Direct characterization of influenza viral NS1 mRNA and related sequences from infected HeLa cells and a cell-free transcription system

The NS1 mRNA of the influenza A virus WSN (H0N1) strain was isolated from a cell-free transcription system, and from the cytoplasm of virus-infected HeLa cells. The 32P-labeled NS1 mRNA derived from the infected cell cytoplasm was characterized by the secondary enzymatic analysis of sixteen of its large or distinct RNAase T1-resistant oligonucleotides. Several WSN strain-specific nucleotide differences from the previously-determined sequence of NS1 mRNA from the PR8 (H0N1) strain of influenza A virus, were located within these sequences. The RNAase T1-resistant oligonucleotides were placed within the primary sequence of NS1 mRNA, using the PR8 strain sequence data. The resulting linear map was then used to identify NS2 mRNA isolated from the infected cell cytoplasm, and an NS-related RNA species generated from NS1 mRNA incubated in a HeLa cell-free extract.

Suppression of the translation defect phenotype specific for a virus-associated RNA-deficient adenovirus mutant in monkey cells by simian virus 40

Human cells infected with adenovirus type 2 (Ad2) or Ad5 require VAI RNA for efficient translation of viral mRNAs at late times after infection. The Ad5 mutant dl-sub720 synthesized neither virus-associated I (VAI) nor VAII RNAs, and infection of human cells with this mutant resulted in reduced virion polypeptide synthesis. Infection of monkey cells with this mutant also resulted in drastic reduction of polypeptide synthesis compared with wild-type (WT) adenovirus infections. Steady-state levels of hexon-specific mRNA were found to be comparable in WT- and mutant-infected monkey cells. The in vitro translation experiments showed that double-mutant- and WT-infected cells contained comparable levels of translatable hexon mRNA (and other adenovirus late mRNAs), suggesting that the severe inhibition of hexon protein synthesis in the VA mutant involves a translation block. Preinfection of monkey cells with simian virus 40 fully restored the efficient translation of this mRNA in the VA mutant infections to the level observed in WT-infected cultures. These results raise the possibility that simian virus 40 may encode or induce factors that suppress the translation block that occurs during adenovirus infections in the absence of the VA RNAs.

Transcription antitermination during influenza viral template RNA synthesis requires the nucleocapsid protein and the absence of a 5' capped end

The first step in the replication of influenza virion RNAs is the synthesis of full-length transcripts of these RNAs. The synthesis of these transcripts, or template RNAs, requires: unprimed initiation rather than the capped RNA-primed initiation used during viral mRNA synthesis, and antitermination at the polyadenylylation site used during mRNA synthesis. To determine the mechanism of template RNA synthesis, we prepared nuclear extracts from infected cells that were active in the synthesis of both template RNAs and viral mRNAs. By providing the dinucleotide ApG as primer, we circumvented the inefficient unprimed initiation catalyzed by these extracts and, as a consequence, were able to focus on the antitermination step. Antitermination, and hence template RNA synthesis, occurred when ApG but not a capped RNA was used as primer, indicating that the presence of a 5' capped end blocked antitermination at the 3' end of the transcript. Ultracentrifugation of the nuclear extract yielded a pellet fraction that contained viral nucleocapsids active in viral mRNA synthesis but not template RNA synthesis and a supernatant fraction that contained the antitermination factor. When the supernatant, which had essentially no activity by itself, was added to the pellet in the presence of ApG, template RNA synthesis was restored. Depletion experiments in which this supernatant was incubated with protein A-Sepharose containing antibodies to individual viral proteins demonstrated that the viral nucleocapsid protein was required for antitermination. The implications of these results for the control of viral RNA replication are discussed.

Translational control by influenza virus: suppression of the kinase that phosphorylates the alpha subunit of initiation factor eIF-2 and selective translation of influenza viral mRNAs

Selective translation of influenza viral mRNAs occurs after influenza virus superinfection of cells infected with the VAI RNA-negative adenovirus mutant dl331 (M. G. Katze, Y.-T. Chen, and R. M. Krug, Cell 37:483-490, 1984). Cell extracts from these doubly infected cells catalyze the initiation of essentially only influenza viral protein synthesis, reproducing the in vivo situation. This selective translation is correlated with a 5- to 10-fold suppression of the dl331-induced kinase that phosphorylates the alpha subunit of eucaryotic initiation factor eIF-2. This strongly suggests that influenza virus encodes a gene product that, analogous to the adenoviral VAI RNA, prevents the shutdown of overall protein synthesis caused by an eIF-2 alpha kinase turned on by viral infection. Adenoviral mRNA translation was restored to the extract from the doubly infected cells by the addition of the guanine nucleotide exchange factor eIF-2B, which is responsible for the normal recycling of eIF-2 during protein synthesis. This indicates that the residual kinase in the doubly infected cells leads to a limitation in functional (nonsequestered) eIF-2B and hence functional (GTP-containing) eIF-2 and that under these conditions influenza viral mRNAs are selectively translated over adenoviral mRNAs. Addition of double-stranded RNA to the extracts from these cells restored the eIF-2 alpha kinase to a level approaching that seen in extracts from cells infected with dl331 alone and caused the inhibition of influenza viral mRNA translation. This suggests that the putative influenza viral gene product acts against the double-stranded RNA activation of the kinase and indicates that influenza viral mRNA translation is also linked to the level of functional eIF-2. Our results thus indicate that a limitation in functional eIF-2 which causes a nonspecific reduction in the rate of initiation of protein synthesis results in the preferential translation of the better mRNAs (influenza viral mRNAs) at the expense of the poorer mRNAs (adenoviral mRNAs).

Adenovirus VAI RNA antagonizes the antiviral action of interferon by preventing activation of the interferon-induced eIF-2 alpha kinase

The VAI RNA of adenovirus is a small, RNA polymerase III-transcribed species required for efficient translation of host cell and viral mRNAs late after infection. The growth of a viral mutant that is unable to produce the RNA is inhibited by interferon, while wild-type virus is not affected. VAI RNA prevents activation of the interferon-induced P1/eIF-2 alpha kinase. This inhibition can be reproduced in extracts of interferon-treated cells where purified VAI RNA prevents activation of latent kinase by double-stranded RNA.

Poly(riboadenylic acid) preferentially inhibits in vitro translation of cellular mRNAs compared with vaccinia virus mRNAs: possible role in vaccinia virus cytopathology

Vaccinia virus-induced inhibition of host protein synthesis seems to be mediated by viral transcripts based on their differential inhibition of cellular mRNA translation in a rabbit reticulocyte lysate system. In this study, we demonstrated that the removal of poly(riboadenylic acid) [poly(A)] from the in vitro viral transcripts abolished this inhibition in the same cell-free system. This observation led us to the finding that less than 1 microM poly(A) completely inhibited HeLa cell mRNA translation in the reticulocyte lysate, whereas only 50% inhibition of vaccinia virus mRNA translation was observed at the same concentration. Similar results were also obtained in a wheat germ protein-synthesizing system. This inhibitory effect of poly(A) was totally abrogated by the addition of polydeoxythymidylate. This selective inhibition was highly specific for poly(A) since other homopolymers, including poly(G), poly(C), and poly(dA), were not capable of causing such an inhibition. Poly(U), however, had a moderate selective inhibitory effect. Among the several mRNAs tested, the translation of L-cell, encephalomyocarditis virus, and reovirus RNAs was also sensitive to poly(A). However, vesicular stomatitis virus mRNA translation was strikingly more resistant. These results suggest that poly(A), which is also synthesized by the virion-associated poly(A) polymerase may be involved in vaccinia virus-mediated host cell shutoff.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

Metabolism and expression of RNA polymerase II transcripts in influenza virus-infected cells

Influenza virus infection has adverse effects on the metabolism of two representative RNA polymerase II transcripts in chicken embryo fibroblasts, those coding for beta-actin and for avian leukosis virus (ALV) proteins. Proviral ALV DNA was integrated into host cell DNA by prior infection with ALV. Within 1 h after influenza virus infection, the rate of transcription of beta-actin and ALV sequences decreased 40 to 60%, as determined by labeling the cells for 5 min with [3H]uridine and by in vitro, runoff assays with isolated nuclei. The transcripts that continued to be synthesized did not appear in the cytoplasm as mature mRNAs, and the kinetics of labeling of these transcripts strongly suggest that they were degraded in the nucleus. By S1 endonuclease assay, it was confirmed that nuclear ALV transcripts disappeared very early after infection, already decreasing ca. 80% by 1 h postinfection. A plausible explanation for this nuclear degradation is that the viral cap-dependent endonuclease in the nucleus cleaves the 5' ends of new polymerase II transcripts, rendering the resulting decapped RNAs susceptible to hydrolysis by cellular nucleases. In contrast to the nuclear transcripts, cytoplasmic beta-actin and ALV mRNAs, which are synthesized before infection, were more stable and did not decrease in amount until after 3 h postinfection. Similar stability of cytoplasmic host cell mRNAs was observed in infected HeLa cells, in which the levels of actin mRNA and two HeLa cell mRNAs (pHe 7 and pHe 28) remained at undiminished levels for 3 h of infection and decreased only slightly by 4.5 h postinfection. The cytoplasmic actin and pHe 7 mRNAs isolated from infected HeLa cells were shown to be translated in reticulocyte extracts in vitro, indicating that host mRNAs were not inactivated by a virus-induced modification. Despite the continued presence of high levels of functional host cell mRNAs, host cell protein synthesis was effectively shut off by about 3 h postinfection in both chicken embryo fibroblasts and HeLa cells. These results are consistent with the establishment of an influenza virus-specific translational system that selectively translates viral and not host mRNAs.

Metabolism and expression of RNA polymerase II transcripts in influenza virus-infected cells

Influenza virus infection has adverse effects on the metabolism of two representative RNA polymerase II transcripts in chicken embryo fibroblasts, those coding for beta-actin and for avian leukosis virus (ALV) proteins. Proviral ALV DNA was integrated into host cell DNA by prior infection with ALV. Within 1 h after influenza virus infection, the rate of transcription of beta-actin and ALV sequences decreased 40 to 60%, as determined by labeling the cells for 5 min with [3H]uridine and by in vitro, runoff assays with isolated nuclei. The transcripts that continued to be synthesized did not appear in the cytoplasm as mature mRNAs, and the kinetics of labeling of these transcripts strongly suggest that they were degraded in the nucleus. By S1 endonuclease assay, it was confirmed that nuclear ALV transcripts disappeared very early after infection, already decreasing ca. 80% by 1 h postinfection. A plausible explanation for this nuclear degradation is that the viral cap-dependent endonuclease in the nucleus cleaves the 5' ends of new polymerase II transcripts, rendering the resulting decapped RNAs susceptible to hydrolysis by cellular nucleases. In contrast to the nuclear transcripts, cytoplasmic beta-actin and ALV mRNAs, which are synthesized before infection, were more stable and did not decrease in amount until after 3 h postinfection. Similar stability of cytoplasmic host cell mRNAs was observed in infected HeLa cells, in which the levels of actin mRNA and two HeLa cell mRNAs (pHe 7 and pHe 28) remained at undiminished levels for 3 h of infection and decreased only slightly by 4.5 h postinfection. The cytoplasmic actin and pHe 7 mRNAs isolated from infected HeLa cells were shown to be translated in reticulocyte extracts in vitro, indicating that host mRNAs were not inactivated by a virus-induced modification. Despite the continued presence of high levels of functional host cell mRNAs, host cell protein synthesis was effectively shut off by about 3 h postinfection in both chicken embryo fibroblasts and HeLa cells. These results are consistent with the establishment of an influenza virus-specific translational system that selectively translates viral and not host mRNAs.