SUMMARY Progressive multifocal leukoencephalopathy (PML) is a debilitating and frequently fatal central nervous system (CNS) demyelinating disease caused by JC virus (JCV), for which there is currently no effective treatment. Lytic infection of oligodendrocytes in the brain leads to their eventual destruction and progressive demyelination, resulting in multiple foci of lesions in the white matter of the brain. Before the mid-1980s, PML was a relatively rare disease, reported to occur primarily in those with underlying neoplastic conditions affecting immune function and, more rarely, in allograft recipients receiving immunosuppressive drugs. However, with the onset of the AIDS pandemic, the incidence of PML has increased dramatically. Approximately 3 to 5% of HIV-infected individuals will develop PML, which is classified as an AIDS-defining illness. In addition, the recent advent of humanized monoclonal antibody therapy for the treatment of autoimmune inflammatory diseases such as multiple sclerosis (MS) and Crohn's disease has also led to an increased risk of PML as a side effect of immunotherapy. Thus, the study of JCV and the elucidation of the underlying causes of PML are important and active areas of research that may lead to new insights into immune function and host antiviral defense, as well as to potential new therapies.
The ability of herpes simplex virus to persist in cells depends on the extent of viral-gene expression, which may be controlled by epigenetic mechanisms. We used quiescent infection with the viral mutants d109 and d106 to explore the effects of cell type and the presence of the viral protein ICP0 on the expression and chromatin structure of the human cytomegalovirus (HCMV) tk and gC promoters on the viral genome. Expression from the HCMV promoter on the d109 genome decreased with time and was considerably less in HEL cells than in Vero cells. Expression from the HCMV promoter in d106 was considerably more abundant than in d109, and this increased with time in both cell types. The same pattern of expression was seen on the tk and gC genes on the viral genomes, although the levels of tk and gC RNA were approximately 10 2 -and 10 5 -fold lower than those of wild-type virus in d106 and d109, respectively. In micrococcal-nuclease digestion experiments, nucleosomes were evident on the d109 genome, and the amount of total H3 as determined by chromatin immunoprecipitation was considerably greater on d109 than d106 genomes. The acetylation of histone H3 on the d106 genomes was evident at early and late times postinfection in Vero cells, but only at late times in HEL cells. The same pattern was observed for H3 acetylated on lysine 9. Trimethylation of H3K9 on d109 genomes was evident only at late times postinfection in Vero cells, while it was observed both early and late in HEL cells. Heterochromatin protein 1␥ (HP1␥) was generally present only on d109 genomes at late times postinfection of HEL cells. The observations of chromatin structure correlate with the expression patterns of the three analyzed genes on the quiescent genomes. Therefore, several mechanisms generally affect the expression and contribute to the silencing of persisting genomes. These are the abundance of nucleosomes, the acetylation state of the histones, and heterochromatin. The extents to which these different mechanisms contribute to repression vary in different cell types and are counteracted by the presence of ICP0.
ICP0 is a transcriptional activating protein required for the efficient replication and reactivation of latent herpes simplex virus 1 (HSV-1). Multiple regions of ICP0 contribute its activity, the most prominent of which appears to be the RING finger, which confers E3 ubiquitin ligase activity. A region in the C terminus of ICP0 has also been implicated in several activities, including the disruption of a cellular repressor complex, REST/CoREST/HDAC1/2/LSD1. We used quiescent infection of MRC-5 cells with a virus that does not express immediate-early proteins, followed by superinfection with various viral mutants to quantify the ability of ICP0 variants to reactivate gene expression and alter chromatin structure. Superinfection with wild-type virus resulted in a 400-fold increase in expression from the previously quiescent d109 genome, the removal of heterochromatin and histones from the viral genome, and an increase in histone marks associated with activated transcription. RING finger mutants were unable to reactivate transcription or remove heterochromatin from d109, while mutants that are unable to bind CoREST activate gene expression from quiescent d109, albeit to a lesser degree than the wild-type virus. One such mutant, R8507, resulted in the partial removal of heterochromatin. Infection with R8507 did not result in the hyperacetylation of H3 and H4. The results demonstrate that (i) consistent with previous findings, the RING finger domain of ICP0 is required for the activation of quiescent genomes, (ii) the RF domain is also crucial for the ultimate removal of repressive chromatin, (iii) activities or interactions specified by the carboxy-terminal region of ICP0 significantly contribute to activation, and (iv) while the effects of the R8507 on chromatin are consistent with a role for REST/CoREST/HDAC1/2/LSD1 in the repression of quiescent genomes, the mutation may also affect other activities involved in derepression.Lytic replication of herpes simplex 1 (HSV-1) occurs in epithelial cells, followed by viral infection of the sensory neurons enervating the site of initial infection. The virus can establish latency in neurons, a state characterized by an almost complete lack of virus gene expression, with the exception of the latency-associated transcript (80, 81). Since latent HSV-1 DNA is not extensively methylated (53) and is found to be packaged in nucleosomes (12), it is likely that chromatin structure participates in repression of the genome and helps to control gene expression. Chromatin can modulate gene expression on a number of levels. Histones can physically impede the access of the transcriptional machinery to the DNA. Certain modifications of the histone tails can recruit repressive or activating proteins to promoters. For example, the repressive chromatin mark trimethylation of histone H3 lysine 9 (H3K9me3) has been shown to form a binding site for, and recruit, heterochromatin protein 1␥ (HP1␥) (1, 54, 64).As in latency in animal models, viral DNA was shown to be in a chromatin structure in a ...
Persisting latent herpes simplex virus genomes are to some degree found in a heterochromatic state, and this contributes to reduced gene expression resulting in quiescence. We used a relatively long-term quiescent infection model in human fibroblasts, followed by provision of ICP0 in trans, to determine the effects of ICP0 on the viral chromatin state as gene expression is reactivated. Expression of ICP0, even at low levels, results in a reduction of higher-order chromatin structure and heterochromatin on quiescent viral genomes, and this effect precedes an increase in transcription. Concurrent with transcriptional activation, high levels of ICP0 expression result in the reduction of the heterochromatin mark trimethylated H3K9, removal of histones H3 and H4 from the quiescent genome, and hyperacetylation of the remaining histones. In contrast, low levels of ICP0 did not appreciably change the levels of histones on the viral genome. These results indicate that ICP0 activity ultimately affects chromatin structure of quiescent genomes at multiple levels, including higher-order chromatin structure, histone modifications, and histone association. Additionally, the level of ICP0 expression affected its ability to change chromatin structure but not to reactivate gene expression. While these observations suggest that some of the effects on chromatin structure are possibly not direct, they also suggest that ICP0 exerts its effects through multiple mechanisms.Herpes simplex virus type 1 (HSV-1) latency is characterized by significantly reduced transcription of the viral genome relative to that seen in productive infection. One gene that appears to be selectively transcribed is that for the latency-associated transcript (LAT) (54,56). This general repression of gene expression suggests that latent gene expression is controlled by epigenetic mechanisms. Since viral DNA is not extensively methylated (33), expression is probably repressed by chromatin structure on the viral genome. During latency, the viral genome is found in an endless, possibly circular, episomal structure, bound by nucleosomes (12, 30) and heterochromatin (12).Periodically in vivo, HSV-1 reactivates, replicates, and can cause recurrent disease. Cellular stress (10,11,39,49,60) and decrease in immune function can both contribute to reactivation (19). Upon reactivation, the full repertoire of viral genes is eventually expressed. The exact order of gene expression upon reactivation is unclear, but latently infected explanted mouse trigeminal ganglia (TG) were shown to express genes in a temporal pattern different from that seen in productive infection (57), while there is also a decrease in LAT expression prior to, or concurrent with, lytic gene expression (55, 60). The relative contributions of viral activators of gene expression to different aspects of the reactivation process are unclear. However, one activator, the immediate-early (IE) protein ICP0, is required for efficient reactivation from latency in vivo (4-6, 26, 27, 31).ICP0 is a promiscuous activa...
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