HSV1 encodes an endoribonuclease termed virion host shutoff (vhs) that is produced late in infection and packaged into virions. Paradoxically, vhs is active against not only host but also virus transcripts, and is involved in host shutoff and the temporal expression of the virus transcriptome. Two other virus proteins—VP22 and VP16 –are proposed to regulate vhs to prevent uncontrolled and lethal mRNA degradation but their mechanism of action is unknown. We have performed dual transcriptomic analysis and single-cell mRNA FISH of human fibroblasts, a cell type where in the absence of VP22, HSV1 infection results in extreme translational shutoff. In Wt infection, host mRNAs exhibited a wide range of susceptibility to vhs ranging from resistance to 1000-fold reduction, a variation that was independent of their relative abundance or transcription rate. However, vhs endoribonuclease activity was not found to be overactive against any of the cell transcriptome in Δ22-infected cells but rather was delayed, while its activity against the virus transcriptome and in particular late mRNA was minimally enhanced. Intriguingly, immediate-early and early transcripts exhibited vhs-dependent nuclear retention later in Wt infection but late transcripts were cytoplasmic. However, in the absence of VP22, not only early but also late transcripts were retained in the nucleus by a vhs-dependent mechanism, a characteristic that extended to cellular transcripts that were not efficiently degraded by vhs. Moreover, the ability of VP22 to bind VP16 enhanced but was not fundamental to the rescue of vhs-induced nuclear retention of late transcripts. Hence, translational shutoff in HSV1 infection is primarily a result of vhs-induced nuclear retention and not degradation of infected cell mRNA. We have therefore revealed a new mechanism whereby vhs and its co-factors including VP22 elicit a temporal and spatial regulation of the infected cell transcriptome, thus co-ordinating efficient late protein production.
A myriad of gene expression strategies has been discovered through studies carried out on viruses. This report concerns the regulation of the HSV-1 vhs endoribonuclease, a virus factor that is important for counteracting host antiviral responses by degrading their mRNAs but that must be regulated during infection to ensure that it does not act against and inhibit the virus itself. We show that regulation of vhs involves multifaceted posttranscriptional cellular and viral processes, including aberrant mRNA localization and a novel, autoregulated negative feedback loop to target its own and coexpressed mRNAs for nuclear retention, an activity that is relieved by coexpression of two other virus proteins, VP22 and VP16. These studies reveal the interplay of strategies by which multiple virus-encoded factors coordinate gene expression at the time that they are needed. These findings are broadly relevant to both virus and cellular gene expression.
Herpes simplex virus type 1 immediate-early protein ICP0 is an E3 ubiquitin ligase of the RING finger class that degrades several cellular proteins during infection. This activity is essential for its functions in stimulating efficient lytic infection and productive reactivation from latency. ICP0 targets a number of proteins that are modified by the small ubiquitin-like SUMO family of proteins, and it includes a number of short sequences that are related to SUMO interaction motifs (SIMs). Therefore, ICP0 has characteristics that are related to those of cellular SUMO-targeted ubiquitin ligase enzymes. Here, we analyze the impact of mutation of a number of SIM-like sequences (SLSs) within ICP0 on HSV-1 replication and gene expression and their requirement for ICP0-mediated degradation of both sumoylated and unmodified promyelocytic leukemia (PML) and other sumoylated cellular proteins. One SLS in the central portion of the ICP0 sequence (SLS4) was found to be absolutely required for targeting cellular sumoylated species in general and sumoylated forms of PML other than those of PML isoform I. Mutation of a group of SLSs in the C-terminal quarter of ICP0 also reduced ICP0-mediated degradation of sumoylated PML in a cooperative manner. Although mutation of individual SLSs caused only modest decreases in viral replication, combined mutation of SLS4 with SLS sequences in the C-terminal quarter of the protein reduced plaque formation efficiency by up to two orders of magnitude. These results provide further evidence that the biological activities of ICP0 are connected with host cell sumoylation events. IMPORTANCEHerpes simplex virus type 1 protein ICP0 plays important roles in regulating the initial stages of lytic infection and productive reactivation from latency. ICP0 mediates its effects through inducing the degradation of cellular proteins that have repressive effects on viral gene expression. An increasing number of cellular proteins are known to be sensitive to ICP0-mediated degradation; therefore, it is important to understand how ICP0 selects its substrates for degradation. This study identifies sequence motifs within ICP0 that are involved in targeting cellular proteins that are modified by the SUMO family of ubiquitin-like proteins and describes how mutation of combinations of these motifs causes a 100-fold defect in viral infectivity. Herpes simplex virus type 1 (HSV-1) immediate-early protein ICP0, a member of the RING finger class of E3 ubiquitin ligases, is required for efficient lytic infection and productive reactivation from latency (1-3). These biological functions of ICP0 require its biochemical ubiquitin ligase activity that results in the degradation of several cellular proteins. While these basic aspects of ICP0 have been firmly established, several questions remain concerning the mechanisms by which ICP0 selects its substrates for degradation and the significance of individual substrates for the outcome of infection. It has long been established that ICP0 initially localizes to cellular...
HSV1 encodes an endoribonuclease termed virion host shutoff (vhs) that is produced late in infection and packaged into virions. Paradoxically, vhs is active against not only host but also virus transcripts, and is involved in host shutoff and the temporal expression of the virus transcriptome. Two other virus proteins - VP22 and VP16 – are proposed to regulate vhs to prevent uncontrolled and lethal mRNA degradation but their mechanism of action is unknown. We have performed dual transcriptomic analysis and single-cell mRNA FISH of human fibroblasts, a cell type where in the absence of VP22, HSV1 infection results in extreme translational shutoff. In Wt infection, host mRNAs exhibited a wide range of susceptibility to vhs ranging from resistance to 1000-fold reduction, a variation that was independent of their relative abundance or transcription rate. However, vhs endoribonuclease activity was not found to be overactive against any of the cell transcriptome in Δ22-infected cells but rather was delayed, while its activity against the virus transcriptome and in particular late mRNA was minimally enhanced. Intriguingly, immediate-early and early transcripts exhibited vhs-dependent nuclear retention later in Wt infection but late transcripts were cytoplasmic. However, in the absence of VP22, not only early but also late transcripts were retained in the nucleus, a characteristic that extended to cellular transcripts that were not efficiently degraded by vhs. Moreover, the ability of VP22 to bind VP16 enhanced but was not fundamental to the rescue of vhs-induced nuclear retention of late transcripts. Hence, translational shutoff in HSV1 infection is primarily a result of vhs-induced nuclear retention and not degradation of infected cell mRNA. We have therefore revealed a new mechanism whereby vhs and its co-factors including VP22 elicit a temporal and spatial regulation of the infected cell transcriptome, thus co-ordinating efficient late protein production.Author SummaryHerpesviruses are large DNA viruses that replicate in the nucleus and express their genes by exploiting host cell mRNA biogenesis mechanisms including transcription, nuclear export, translation and turnover. As such, these viruses express multiple factors that enable the appropriation of cellular pathways for optimal virus production, and work in concert to shut off host gene expression and to overexpress virus genes in a well-described cascade that occurs in a temporal pattern of immediate-early, early and late proteins. We have analysed global and single cell changes in the host and virus transcriptome to uncover a novel mechanism by which the viral endoribonuclease, termed vhs, turns off early virus gene expression. This is achieved through the vhs-induced nuclear retention of the entire infected cell transcriptome at the onset of late gene expression. To enable the switch from early to late protein production the virus then requires a second factor called VP22 to specifically inhibit the nuclear retention of late transcripts allowing their translation in the cytoplasm. In this way, HSV1 elicits a temporal and spatial regulation of the infected cell transcriptome to co-ordinate efficient late protein production, a process that may be relevant to herpesviruses in general.
Herpes simplex virus 1 (HSV1) expresses its genes in a classical cascade culminating in the production of large amounts of structural proteins to facilitate virus assembly. HSV1 lacking the virus protein VP22 (Δ22) exhibits late translational shutoff, a phenotype that has been attributed to the unrestrained activity of the virion host shutoff (vhs) protein, a virus-encoded endoribonuclease which induces mRNA degradation during infection. We have previously shown that vhs is also involved in regulating the nuclear-cytoplasmic compartmentalisation of the virus transcriptome, and in the absence of VP22 a number of virus transcripts are sequestered in the nucleus late in infection. Here we show that despite expressing minimal amounts of structural proteins and failing to plaque on human fibroblasts, the strain 17 Δ22 virus replicates and spreads as efficiently as Wt virus, but without causing cytopathic effect (CPE). Nonetheless, CPE-causing virus spontaneously appeared on Δ22-infected human fibroblasts, and four viruses isolated in this way had all acquired point mutations in vhs which rescued late protein translation. However, unlike a virus deleted for vhs, these viruses still induced the degradation of both cellular and viral mRNA suggesting that vhs mutation in the absence of VP22 is necessary to overcome a more complex disturbance in mRNA metabolism than mRNA degradation alone. The ultimate outcome of secondary mutations in vhs is therefore the rescue of virus-induced CPE caused by late protein synthesis, and while there is a clear selective pressure on HSV1 to mutate vhs for optimal production of late structural proteins, the purpose of this is over and above that of virus production.
Herpes simplex virus 1 (HSV1) expresses its genes in a classical cascade culminating in the production of large amounts of structural proteins to facilitate virus assembly. HSV1 lacking the virus protein VP22 (Δ22) exhibits late translational shutoff, a phenotype that has been attributed to the unrestrained activity of the virion host shutoff (vhs) protein, a virusencoded endoribonuclease which induces mRNA degradation during infection. We have previously shown that vhs is also involved in regulating the nuclear-cytoplasmic compartmentalisation of the virus transcriptome, and in the absence of VP22 many virus transcripts are sequestered in the nucleus late in infection. Here we show that despite expressing minimal amounts of structural proteins and failing to plaque on human fibroblasts, the strain 17 Δ22 virus replicates and spreads as efficiently as Wt virus, but without causing cytopathic effect (CPE). Nonetheless, CPE-causing virus spontaneously appeared on Δ22-infected human fibroblasts, and four viruses isolated in this way had all acquired point mutations in vhs which rescued viral mRNA export and late protein translation. However, unlike a virus deleted for vhs, these viruses still induced the degradation of cellular mRNA, suggesting that vhs mutation in the absence of VP22 is necessary to overcome a disturbance in mRNA export rather than mRNA degradation. The ultimate outcome of secondary mutations in vhs is therefore the rescue of virus-induced CPE caused by late protein synthesis, and while there is a clear selective pressure on HSV1 to mutate vhs for optimal production of late structural proteins, the purpose of this is over and above that of virus production.
Since the emergence of SARS-CoV-2, global monitoring of the virus using whole genome sequencing has identified mutations occurring across the viral genome. Whilst the majority have little impact on the virus, they are used effectively to monitor the movement of the virus globally and to inform locally on transmission chains. In late 2020, a variant of SARS-CoV-2 (B.1.1.7 - VOC 202012/01) was identified in the UK with a distinct constellation of mutations, including in the spike gene that increased transmissibility. A deletion in spike also affected one of the screening qPCR tests being used in the UK outside of Wales, causing a failure to detect the target. This quickly became a surrogate marker for the variant to allow rapid monitoring of the virus as it seeded into new regions of the UK. A screening study using this assay as a proxy marker, was undertaken to understand the prevalence of the variant in Wales. Secondary analysis of a screening qPCR targeting N and ORF and also included an endogenous control, was also performed to understand viral load excretion in those infected with the variant compared to other circulating lineages. Using a combination of analytical methods based on the Ct values of two gene targets normalised against the endogenous control, there was a difference in the excreted viral load. Those with the variant excreting more virus than those not infected with the variant. Supporting not only increased infectivity but offering a plausible reason why increased transmission was associated with this particular variant. Whilst there are limitations in this study, the method using Ct as a proxy for viral load can be used at the population level to determine differences in viral excretion kinetics associated with different variants.
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