Semipermissive Replication of a Nuclear Polyhedrosis Virus of Autographa californica in a Gypsy Moth Cell Line

Several gypsy moth cell lines have been previously described as nonpermissive for the multiple-embedded nuclear polyhedrosis virus of Autographa californica (AcMNPV). In this report, we demonstrate the semipermissive infection of a gypsy moth cell line, IPLB-LD-652Y, with AcMNPV. IPLB-LD-652Y cells infected with AcMNPV produced classic cytopathic effects but failed to yield infectious progeny virus. Results of experiments employing DNA-DNA dot hybridization suggested that AcMNPV DNA synthesis was initiated from 8 to 12 h postinfection (p.i.), continued at a maximum rate from 12 to 20 h p.i., and declined from 20 to 36 h p.i. The rate of AcMNPV DNA synthesis approximated that observed in the permissive TN-368 cell line. AcMNPV-infected IPLB-LD-652Y cells, pulse-labeled with [(35)S]methionine at various time intervals p.i. and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, revealed four virus-induced proteins, one novel to the semipermissive system and three early alpha proteins, synthesized from 1 to 20 h p.i. Thereafter, both host and viral protein synthesis was completely suppressed. These results suggest that AcMNPV adsorbed, penetrated, and initiated limited macromolecular synthesis in the semipermissive gypsy moth cell line. However, the infection cycle was restricted during the early phase of AcMNPV replication.     

Responses of insect cells to baculovirus infection: protein synthesis shutdown and apoptosis.

Protein synthesis is globally shut down at late times postinfection in the baculovirus Autographa californica M nuclear polyhedrosis virus (AcMNPV)-infected gypsy moth cell line Ld652Y. A single gene, hrf-1, from another baculovirus, Lymantria dispar M nucleopolyhedrovirus, is able to preclude protein synthesis shutdown and ensure production of AcMNPV progeny in Ld652Y cells (S. M. Thiem, X. Du, M. E. Quentin, and M. M. Berner, J. Virol. 70:2221-2229, 1996; X. Du and S. M. Thiem, Virology 227:420-430, 1997). AcMNPV contains a potent antiapoptotic gene, p35, and protein synthesis arrest was reported in apoptotic insect cells induced by infection with AcMNPV lacking p35. In exploring the function of host range factor 1 (HRF-1) and the possible connection between protein synthesis shutdown and apoptosis, a series of recombinant AcMNPVs with different complements of p35 and hrf-1 were employed in apoptosis and protein synthesis assays. We found that the apoptotic suppressor AcMNPV P35 was translated prior to protein synthesis shutdown and functioned to prevent apoptosis. HRF-1 prevented protein synthesis shutdown even when the cells were undergoing apoptosis, but HRF-1 could not functionally substitute for P35. The DNA synthesis inhibitor aphidicolin could block both apoptosis and protein synthesis shutdown in Ld652Y cells infected with p35 mutant AcMNPVs but not the protein synthesis shutdown in wild-type AcMNPV-infected Ld652Y cells. These data suggest that protein synthesis shutdown and apoptosis are separate responses of Ld652Y cells to AcMNPV infection and that P35 is involved in inducing a protein synthesis shutdown response in the absence of late viral gene expression in Ld652Y cells. A model was developed for these responses of Ld652Y cells to AcMNPV infection.     

Identification of baculovirus gene that promotes Autographa californica nuclear polyhedrosis virus replication in a nonpermissive insect cell line.

A gene that promotes Autographa californica M nuclear polyhedrosis virus (AcMNPV) replication in IPLB-Ld652Y cells, a cell line that is nonpermissive for AcMNPV, was identified in Lymantria dispar M nuclear polyhedrosis virus (LdMNPV). Cotransfection of AcMNPV DNA and a plasmid carrying the LdMNPV gene into IPLB-Ld652Y cells results in AcMNPV replication. The gene maps between 43.3 and 43.8 map units on the 162-kbp genome of LdMNPV. It comprises a 218-codon open reading frame and encodes a polypeptide with a predicted molecular mass of 25.7 kDa. The predicted polypeptide is glutamic acid and valine rich and negatively charged, with a pI of 4.61. No protein sequence motifs were identified, and no matches with known nucleotide or peptide sequences were found in the AcMNPV genome or database searches that suggest how this gene might function. A recombinant AcMNPV bearing the LdMNPV gene overcomes a block in protein synthesis observed in AcMNPV-infected IPLB-Ld652Y cells. Using Southern blotting techniques, we were unable to identify a homolog in Orgyia pseudotsugata M nuclear polyhedrosis virus, a baculovirus that is routinely propagated in IPLB-Ld652Y cells. This suggests that the LdMNPV host range is unique among the baculoviruses studied to date. We named this gene hrf-1 (for host range factor 1).     

Differential requirements for baculovirus late expression factor genes in two cell lines.

A plasmid library of 18 late expression factor (LEF) genes (LEF library) from the baculovirus Autographa californica nuclear polyhedrosis virus (AcMNPV) supports transient expression from a late viral promoter in the SF-21 cell line, derived from Spodoptera frugiperda. We found, however, that this LEF library was unable to support expression from the same promoter in the TN-368 cell line, derived from Trichoplusia ni, which is also permissive for AcMNPV replication. To identify the additional factor(s) required for expression in TN-368 cells, we cotransfected the LEF library with clones representing portions of the AcMNPV genome not represented in the LEF library. A single additional gene was identified; this gene corresponded to ORF70 of the complete AcMNPV sequence and potentially encodes a 34-kDa cysteine-rich polypeptide. Because of its differential effect on late gene expression in the two cell lines, we renamed ORF70 hcf-1 (for host cell-specific factor 1). hcf-1 was involved in expression from reporter plasmids under late and very late but not early promoter control, indicating that it was also a LEF gene. Plasmid DNA replication assays indicated that HCF-1 was involved in virus origin-specific DNA replication in TN-368 cells. Three LEF genes, ie-2, lef-7, and p35, required for optimal virus origin-specific plasmid DNA replication or stability in SF-21 cells had little or no influence in TN-368 cells. Thus, as determined by transient-expression assays, cell line-specific and potentially host-specific factors are required for origin-specific DNA replication or stability.     

Encephalomyocarditis Virus Infection of Mouse Plasmacytoma Cells I. Inhibition of Cellular Protein Synthesis

Mouse plasmacytoma ascites tumor cells (MOPC 460) were efficiently infected with encephalomyocarditis virus. Inhibition of host protein synthesis was evident after 2 h and complete by 4 h postinfection. The mechanism by which virus infection results in inhibition of host cell protein synthesis was studied in vitro. Cell-free protein-synthesizing systems, prepared from uninfected and infected cells, were found to be equally active with respect to their abilities to translate cellular and viral mRNAs. The plasmacytoma cell-free system was also shown to be insensitive to the addition of double-stranded viral RNA. Host cellular mRNA was isolated from uninfected and infected cells. No difference in the amount or size distribution of the mRNA was detected. However, the mRNA from infected cells was translated only 46 to 49% as actively as that from uninfected cells. mRNA isolated from cells in which initiation of protein synthesis was inhibited with pactamycin was similarly inactivated. Simultaneous addition of viral RNA and cellular mRNA to the plasmacytoma cell-free system resulted in a complete suppression of the translation of the cellular message, whereas viral RNA was translated normally.     

Mengovirus leader is involved in the inhibition of host cell protein synthesis.

The presence of a leader peptide in picornaviruses is restricted to the Cardiovirus and Aphthovirus genera. However, the leader peptides of these two genera are structurally and functionally unrelated. The aphthovirus leader is a protease involved in viral polyprotein processing and host cell translation shutoff. The function of the cardiovirus leader peptide is still unknown. To gain an insight into the function of the cardiovirus leader peptide, a mengovirus leader peptide deletion mutant was constructed. The deletion mutant was able to grow at a reduced rate in baby hamster kidney cells (BHK-21). Mutant virus production in mouse fibroblasts (L929 cells), however, could be demonstrated only after inoculation of BHK-21 cells with the transfected L929 cells. Analysis of cellular and viral protein synthesis in mutant virus-infected cells showed a delayed inhibition of host cell protein synthesis and a reduced production of viral proteins. In a single-cycle infection, mutant virus produced only 1% of wild-type virus yield at 8 h postinfection. Host cell translation shutoff in L929 cells infected with mutant virus was restored by the addition of the kinase inhibitor 2-aminopurine. Mutant virus production in 2-aminopurine-treated L929 cells was increased to 60% of wild-type virus yield at 8 h postinfection. Our results suggest that the cardiovirus leader peptide is involved in the inhibition of host cell protein synthesis.     

Monensin and nigericin prevent the inhibition of host translation by poliovirus, without affecting p220 cleavage.

Addition of monensin or nigericin after poliovirus entry into HeLa cells prevents the inhibition of host protein synthesis by poliovirus. The infected cells continue to synthesize cellular proteins at control levels for at least 8 h after infection in the presence of the ionophore. Cleavage of p220 (gamma subunit of eukaryotic initiation factor 4 [eIF-4 gamma]), a component of the translation initiation factor eIF-4F, occurs to the same extent in poliovirus-infected cells whether or not they are treated with monensin. Two hours after infection there is no detectable intact p220, but the cells continue to translate cellular mRNAs for several hours at levels similar to those in uninfected cells. Nigericin or monensin prevented the arrest of host translation at all the multiplicities of poliovirus infection tested. At high multiplicities of infection, an unprecedented situation was found: cells synthesized poliovirus and cellular proteins simultaneously. Superinfection of vesicular stomatitis virus-infected HeLa cells with poliovirus led to a profound inhibition of vesicular stomatitis virus protein synthesis, while nigericin partially prevented this blockade. Drastic inhibition of translation also took place in influenza virus-infected Vero cells treated with nigericin and infected with poliovirus. These findings suggest that the translation of newly synthesized mRNAs is dependent on the integrity of p220, while ongoing cellular protein synthesis does not require an intact p220. The target of ionophore action during the poliovirus life cycle was also investigated. Addition of nigericin at any time postinfection profoundly blocked the synthesis of virus RNA, whereas viral protein synthesis was not affected if nigericin was added at 4 h postinfection. These results agree well with previous findings indicating that inhibitors of phospholipid synthesis or vesicular traffic interfere with poliovirus genome replication. Therefore, the action of nigericin on the vesicular system may affect poliovirus RNA synthesis. In conclusion, monensin and nigericin are potent inhibitors of poliovirus genome replication that prevent the shutoff of host translation by poliovirus while still permitting cleavage of p220.     

Shut-off of actin biosynthesis in adenovirus serotype-2-infected cells

Adenovirus produces a dramatic shut-off of host protein synthesis after infection of HeLa cells. The level of actin messenger RNAs remained relatively unchanged after viral infection, when assayed by in vitro translation and two-dimensional gel electrophoresis analysis of the proteins or hybridization of the total cytoplasmic RNAs to the human actin gene. The distribution of actin mRNA in the polyribosomes is altered after adenovirus infection, with small polyribosomes and monoribosomes of the infected cells occupied by actin messages untranslatable in a rabbit reticulocyte lysate. The large polyribosomes still retain enough functional mRNAs to provide significant levels of actin protein in a rabbit reticulocyte in vitro translation system. In contrast, in homologous infected cell lysates, the translation of exogenous actin mRNA is greatly reduced when compared to uninfected HeLa cell lysates. In nuclease-treated uninfected or infected HeLa cell-free extracts, translation of viral mRNA is equally efficient and higher than that of actin mRNA. Thus, translational regulatory mechanisms which include inactivation of a part of the actin mRNA population accompanied by displacement to small polysomes and/or virus-induced modification of the cellular translational machinery to discriminate against cellular actin mRNA seem to account for the sharp reduction in actin protein synthesis of adenovirus-infected cells.     

Replication and passage of alfalfa looper nuclear polyhedrosis virus plaque variants in cloned cell cultures and larval stages of four host species

As alfalfa looper nuclear polyhedrosis virus (NPV) was serially passed through TN-368 cell cultures, the percentage of the cell population that developed infection with the MP variant decreased, while cells infected with FP variant increased. The MP variant was more virulent to Trichoplusia ni than the FP variant. Cells from the TN-368 cell line and strains derived from single cells were infected with isolated MP plaques. The viral progeny remained homogenous after one or occasionally two passages in cultured TN-368 cells. However, further serial passes in TN-368 cells or one pass in cell strains resulted in loss of the homogeneity, and the FP variant was detected. Four species of Lepidopterous larvae were also infected with the MP variant. Both variants were detected in viral progeny from diseased larvae.     

Reversion by hypotonic medium of the shutoff of protein synthesis induced by encephalomyocarditis virus.

Infection of human HeLa cells by picornaviruses produces a drastic inhibition of host protein synthesis. Treatment of encephalomyocarditis virus-infected HeLa cells with hypotonic medium reversed this inhibition; no viral protein synthesis was detected. The blockade of viral translation by hypotonic conditions was observed for a wide range of multiplicities of infection. However, only with low virus-to-cell ratios did cellular protein synthesis resume. The ratio of cellular to viral mRNA translation was strongly influenced by the concentration of monovalent ions present in the culture medium: a high concentration of NaCl or KCl favored the translation of viral mRNA and strongly inhibited cellular protein synthesis, whereas the opposite was true when NaCl was omitted from the culture medium. Once viral protein synthesis had been blocked by hypotonic medium treatment, it resumed when the infected cells were placed in a normal or hypertonic medium, indicating that the viral components synthesized in the infected cells were not destroyed by this treatment. These observations reinforced the idea that ions play a role in discriminating between viral and cellular mRNA translation in virus-infected animal cells.     

Viral subversion of the host protein synthesis machinery

Viruses are fully reliant on the translation machinery of their host cells to produce the polypeptides that are essential for viral replication. Consequently, viruses recruit host ribosomes to translate viral mRNAs, typically using virally encoded functions to seize control of cellular translation factors and the host signalling pathways that regulate their activity. This not only ensures that viral proteins will be produced, but also stifles innate host defences that are aimed at inhibiting the capacity of infected cells for protein synthesis. Remarkably, nearly every step of the translation process can be targeted by virally encoded functions. This Review discusses the diverse strategies that viruses use to subvert host protein synthesis functions and regulate mRNA translation in infected cells.     

Early and late functions in a bipartite RNA virus: evidence for translational control by competition between viral mRNAs.

It has been shown previously that Drosophila cells infected with black beetle virus synthesize an early viral protein, protein A, a putative element of the viral RNA polymerase. Synthesis of protein A declines sharply by 6 h postinfection, whereas synthesis of viral coat protein alpha continues for at least 14 h. The early shutoff in protein A synthesis occurred despite the presence of equimolar proportions of the mRNAs for proteins A and alpha, RNAs 1 and 2, respectively. We have now been able to mimic this translational discrimination in a cell-free protein-synthesizing system prepared from infected or uninfected Drosophila cells, thus allowing further analysis of the mechanism by which translation of RNA 1 is selectively turned off. The results revealed no evidence for control by virus-encoded proteins or by virus-induced modification of mRNAs by the cell-free system. Rather, with increasing RNA concentration, viral RNA 1 was outcompeted by its genomic partner, RNA 2. This suggests that the early shutoff in intracellular synthesis of protein A is due to decreasing ability of RNA 1 to compete for a rate-controlling translational factor(s) as the concentration of viral RNAs accumulates within the infected cell.     

Translational control in influenza virus-infected cells

Influenza virus type A has been shown to establish a translational control system such that during infection there is a dramatic inhibition of host cell protein synthesis and viral mRNAs are selectively and efficiently translated. The following review summarizes the complex strategies employed by influenza to accomplish these goals. These include: (i) preventing newly made cellular mRNAs from entering the cytoplasm of infected cells; (ii) inhibiting the initiation and elongation steps of translation of preexisting cellular mRNAs; (iii) possessing RNAs with structural features which enhance translation; (iv) encoding mechanisms to downregulate the interferon induced protein kinase thus allowing overall protein synthesis levels to remain high.