Vesicular stomatitis virus in Drosophila melanogaster cells: regulation of viral transcription and replication

Drosophila Schneider 2 (S2) cells: a novel tool for studying HSV-induced membrane fusion

Drosophila S2 cells and mammalian CHO-K1 cells were used to investigate the requirements for HSV-1 cell fusion. Infection assays indicated S2 cells were not permissive for HSV-1. HVEM and nectin-1 mediated cell fusion between CHO-K1 cells and S2 cells when either CHO-K1 or S2 cells were used as target cells. Interestingly, PILRα did not mediate fusion between CHO-K1 or S2 cells due to a glycosylation defect of PILRα and gB in S2 cells. Fusion activity was not detected for any receptor tested when S2 cells were used both as target cells and effector cells indicating S2 cells may lack a key cellular factor present in mammalian cells that is required for cell fusion. Thus, insect cells may provide a novel tool to study the interaction of HSV-1 glycoproteins and cellular factors required for fusion, as well as a means to identify unknown cellular factors required for HSV replication.

RNAi screening for host factors involved in Vaccinia virus infection using Drosophila cells

Viral pathogens represent a significant public health threat; not only can viruses cause natural epidemics of human disease, but their potential use in bioterrorism is also a concern. A better understanding of the cellular factors that impact infection would facilitate the development of much-needed therapeutics. Recent advances in RNA interference (RNAi) technology coupled with complete genome sequencing of several organisms has led to the optimization of genome-wide, cell-based loss-of-function screens. Drosophila cells are particularly amenable to genome-scale screens because of the ease and efficiency of RNAi in this system ¹. Importantly, a wide variety of viruses can infect Drosophila cells, including a number of mammalian viruses of medical and agricultural importance ^2,3,4. Previous RNAi screens in Drosophila have identified host factors that are required for various steps in virus infection including entry, translation and RNA replication ⁵. Moreover, many of the cellular factors required for viral replication in Drosophila cell culture are also limiting in human cells infected with these viruses ^{4,6,7,8, 9}. Therefore, the identification of host factors co-opted during viral infection presents novel targets for antiviral therapeutics. Here we present a generalized protocol for a high-throughput RNAi screen to identify cellular factors involved in viral infection, using vaccinia virus as an example.

TRIM22 E3 ubiquitin ligase activity is required to mediate antiviral activity against encephalomyocarditis virus

The interferon (IFN) system is a major effector of the innate immunity that allows time for the subsequent establishment of an adaptive immune response against a wide-range of pathogens. Their diverse biological actions are thought to be mediated by the products of specific but usually overlapping sets of cellular genes induced in the target cells. Ubiquitin ligase members of the tripartite motif (TRIM) protein family have emerged as IFN-induced proteins involved in both innate and adaptive immunity. In this report, we provide evidence that TRIM22 is a functional E3 ubiquitin ligase that is also ubiquitinated itself. We demonstrate that TRIM22 expression leads to a viral protection of HeLa cells against encephalomyocarditis virus infections. This effect is dependent upon its E3 ubiquitinating activity, since no antiviral effect was observed in cells expressing a TRIM22-deletion mutant defective in ubiquitinating activity. Consistent with this, TRIM22 interacts with the viral 3C protease (3C(PRO)) and mediates its ubiquitination. Altogether, our findings demonstrate that TRIM22 E3 ubiquitin ligase activity represents a new antiviral pathway induced by IFN against picornaviruses.

Antagonistic pleiotropy involving promoter sequences in a virus

Selection of specialist genotypes, that is, populations with limited niche width, promotes the maintenance of diversity. Specialization to a particular environment may have a cost in other environments, including fitness tradeoffs. When the tradeoffs are the result of mutations that have a beneficial effect in the selective environment but a deleterious effect in other environments, we have antagonistic pleiotropy. Alternatively, tradeoffs can result from the fixation of mutations that are neutral in the selective environment but have a negative effect in other environments, and thus the tradeoff is due to mutation accumulation. We tested the mechanisms underlying the fitness tradeoffs observed during adaptation to persistent infection of vesicular stomatitis virus in insect cells by sequencing the full-length genomes of 12 strains with a history of replication in a single niche (acute mammalian infection or persistent insect infection) or in temporally heterogeneous niches and correlated genetic and fitness changes. Ecological theory predicts a correlation between the selective environment and the niche width of the evolved populations, such that adaptation to single niches should lead to the selection of specialists and niche cycling should result in the selection of generalists. Contrary to this expectation, adaptation to one of the single niches resulted in a generalist and adaptation to a heterogeneous environment led to the selection of a specialist. Only one-third of the mutations that accumulated during persistent infection had a fitness cost that could be explained in all cases by antagonistic pleiotropy. Mutations involved in fitness tradeoffs included changes in regulatory sequences, particularly at the 3' termini of the genomes, which contain the single promoter that controls viral transcription and replication.

ISG20, a new interferon-induced RNase specific for single-stranded RNA, defines an alternative antiviral pathway against RNA genomic viruses

Interferons (IFNs) encode a family of secreted proteins that provide the front-line defense against viral infections. Their diverse biological actions are thought to be mediated by the products of specific but usually overlapping sets of cellular genes induced in the target cells. We have recently isolated a new human IFN-induced gene that we have termed ISG20, which codes for a 3' to 5' exonuclease with specificity for single-stranded RNA and, to a lesser extent, for DNA. In this report, we demonstrate that ISG20 is involved in the antiviral functions of IFN. In the absence of IFN treatment, ISG20-overexpressing HeLa cells showed resistance to infections by vesicular stomatitis virus (VSV), influenza virus, and encephalomyocarditis virus (three RNA genomic viruses) but not to the DNA genomic adenovirus. ISG20 specifically interfered with VSV mRNA synthesis and protein production while leaving the expression of cellular control genes unaffected. No antiviral effect was observed in cells overexpressing a mutated ISG20 protein defective in exonuclease activity, demonstrating that the antiviral effects were due to the exonuclease activity of ISG20. In addition, the inactive mutant ISG20 protein, which is able to inhibit ISG20 exonuclease activity in vitro, significantly reduced the ability of IFN to block VSV development. Taken together, these data suggested that the antiviral activity of IFN against VSV is partly mediated by ISG20. We thus show that, besides RNase L, ISG20 has an antiviral activity, supporting the idea that it might represent a novel antiviral pathway in the mechanism of IFN action.

Study of the ref(2)P locus of Drosophila melanogaster. II. Genetic studies of the 37DF region

The ref(2)P gene of Drosophila melanogaster is implicated in sigma rhabdovirus multiplication. Two common alleles of ref(2)P are known, ref(2)P0 which permits sigma virus multiplication and ref(2)Pp which is restrictive for most sigma virus strains. This gene maps to the cytogenetic region 37E3-F3. Using Df(2L)E55 (= Df(2L)37D2-E1;37F5-38A1), we have screened for lethal, semi-lethal and visible mutations following diepoxybutane (DEB) or ethyl methanesulfonate (EMS) mutagenesis. Our data confirm than DEB is more efficient than EMS at inducing deletions. The mutations obtained in this region define 14 complementation groups. One of them, l(2)37Dh, appears to be a general enhancer of Minute and Minute-like mutations. None of the mutations were allelic to the ref(2)P locus. Loss-of-function alleles of ref(2)P (called null) were selected following DEB mutagenesis. Homozygous or hemizygous ref(2)Pnull flies are male sterile. These flies, like homozygous or hemizygous ref(2)P0 flies, are fully permissive for sigma virus replication. We suggest that the ref(2)P products interact with viral products, but that this interaction is not necessary for an efficient viral cycle.

Genetic resistance to viral infection: the molecular cloning of a Drosophila gene that restricts infection by the rhabdovirus sigma

The ref(2)P gene of Drosophila melanogaster has two common alleles, ref(2)Po which permits the infection of flies by the rhabdovirus sigma (sigma), and ref(2)Pp which is restrictive for sigma infection. This gene has been cloned by P element tagging and shown to code for two RNAs in adult flies. These RNAs are expressed in both males and females, but only the larger is expressed in ovaries. Both transcripts are shorter, by about 50 nucleotides, in flies carrying the ref(2)Pp allele than in those carrying ref(2)Po. The dominance relationships of these two alleles, and the fact that ref(2)Pnull alleles are permissive to sigma infection, suggest that the ref(2)Po product is antimorphic to that of the ref(2)Pp allele.