An RNA polymerase II transcription factor inactivated in poliovirus-infected cells copurifies with transcription factor TFIID

Picornaviruses and nuclear functions: targeting a cellular compartment distinct from the replication site of a positive-strand RNA virus

The compartmentalization of DNA replication and gene transcription in the nucleus and protein production in the cytoplasm is a defining feature of eukaryotic cells. The nucleus functions to maintain the integrity of the nuclear genome of the cell and to control gene expression based on intracellular and environmental signals received through the cytoplasm. The spatial separation of the major processes that lead to the expression of protein-coding genes establishes the necessity of a transport network to allow biomolecules to translocate between these two regions of the cell. The nucleocytoplasmic transport network is therefore essential for regulating normal cellular functioning. The Picornaviridae virus family is one of many viral families that disrupt the nucleocytoplasmic trafficking of cells to promote viral replication. Picornaviruses contain positive-sense, single-stranded RNA genomes and replicate in the cytoplasm of infected cells. As a result of the limited coding capacity of these viruses, cellular proteins are required by these intracellular parasites for both translation and genomic RNA replication. Being of messenger RNA polarity, a picornavirus genome can immediately be translated upon entering the cell cytoplasm. However, the replication of viral RNA requires the activity of RNA-binding proteins, many of which function in host gene expression, and are consequently localized to the nucleus. As a result, picornaviruses disrupt nucleocytoplasmic trafficking to exploit protein functions normally localized to a different cellular compartment from which they translate their genome to facilitate efficient replication. Furthermore, picornavirus proteins are also known to enter the nucleus of infected cells to limit host-cell transcription and down-regulate innate antiviral responses. The interactions of picornavirus proteins and host-cell nuclei are extensive, required for a productive infection, and are the focus of this review.

Viral subversion of host functions for picornavirus translation and RNA replication

Picornavirus infections lead to symptoms that can have serious health and economic implications. The viruses in this family (Picornaviridae) have a small genomic RNA and must rely on host proteins for efficient viral gene expression and RNA replication. To ensure their effectiveness as pathogens, picornaviruses have evolved to utilize and/or alter host proteins for the benefit of the virus life cycle. This review discusses the host proteins that are subverted during infection to aid in virus replication. It will also describe proteins and functions that are altered during infection for the benefit of the virus.

Poliovirus infection blocks ERGIC-to-Golgi trafficking and induces microtubule-dependent disruption of the Golgi complex

Cells infected with poliovirus exhibit a rapid inhibition of protein secretion and disruption of the Golgi complex. Neither the precise step at which the virus inhibits protein secretion nor the fate of the Golgi complex during infection has been determined. We find that transport-vesicle exit from the endoplasmic reticulum (ER) and trafficking to the ER-Golgi intermediate compartment (ERGIC) are unaffected in the poliovirus-infected cell. By contrast, poliovirus infection blocks transport from the ERGIC to the Golgi complex. Poliovirus infection also induces fragmentation of the Golgi complex resulting in diffuse distribution of both large and small vesicles throughout the cell. Pre-treatment with nocodazole prevents complete fragmentation, indicating that microtubules are required for poliovirus-induced Golgi dispersion. However, virally induced inhibition of the secretory pathway is not affected by nocodazole, and Golgi dispersion was found to occur during infection with mutant viruses with reduce ability to inhibit protein secretion. We conclude that the dispersion of the Golgi complex is not in itself the cause of inhibition of traffic between the ERGIC and the Golgi. Instead, these phenomena are independent effects of poliovirus infection on the host secretory complex.

The interaction of cytoplasmic RNA viruses with the nucleus

Mammalian cells infected with poliovirus, the prototype member of the picornaviridae family, undergo rapid macromolecular and metabolic changes resulting in efficient replication and release of virus from infected cells. Although this virus is predominantly cytoplasmic, it does shut-off transcription of all three cellular transcription systems. Both biochemical and genetic studies have shown that a virally encoded protease, 3C(pro), is responsible for host cell transcription shut-off. The 3C protease cleaves a number of RNA polymerase II transcription factors including the TATA-binding protein (TBP), the cyclic AMP-responsive element binding protein (CREB), the Octamer binding protein (Oct-1), p53, and RNA polymerase III transcription factor IIICalpha, and Polymerase I factor SL-1. Most of these cleavages occur at glutamine-glycine bonds. Additionally, a second viral protease, 2A(pro), also cleaves TBP at a tyrosine-glycine bond. The latter cleavage could be responsible for shut-off of small nuclear RNA transcription. Recent studies indicate that the viral protease-polymerase precursor 3CD can enter nucleus in poliovirus-infected cells. The nuclear localization signal (NLS) present within the 3D sequence appears to play a role in the nuclear entry of 3CD. Thus, 3C may be delivered to the infected cell nucleus in the form the precursor 3CD or other 3C-containing precursors. Auto-proteolytic cleavage of these precursors could then generate 3C. Thus, for a small RNA virus that strictly replicates in the cytoplasm, a portion of its life cycle does include interaction with the host cell nucleus.

Poliovirus 3C protease-mediated degradation of transcriptional activator p53 requires a cellular activity

Infection of HeLa cells with poliovirus leads to rapid shut-off of host cell transcription by RNA polymerase II. Previous results have suggested that both the basal transcription factor TBP (TATA-binding protein) and transcription activator proteins such as CREB (cyclic AMP-responsive element-binding protein) and Oct-1 (the octamer-binding factor) are cleaved by the viral-encoded protease, 3C(Pro). Here we demonstrate that the transcriptional activator (and tumor suppressor) p53 is degraded by the viral protease 3C both in vivo and in vitro. Unlike other transcription factors that are directly cleaved by 3C(pro), degradation of p53 requires a HeLa cell activity in addition to 3C(Pro). The degradation of p53 by 3C(Pro) does not appear to involve the ubiquitin pathway of protein degradation. Vaccinia virus infection of HeLa cells leads to inactivation of the cellular activity required for 3C(Pro)-mediated degradation of p53. The vaccinia-encoded protein (CrmA) is known to inhibit caspase I (ICE protease) that converts inactive IL-1beta to an active secreted form. Incubation of HeLa cells with caspase I inhibitor Z-VAD-fmk does not interfere with 3C(Pro)-mediated degradation of p53. The cellular activity present in extracts of HeLa cells can be fractionated through phosphocellulose. A partially purified fraction that elutes at 0.6 M KCl from phosphocellulose contains the activity that degrades p53 in a 3C(Pro)-dependent manner. These results suggest that both poliovirus-encoded protease 3C(Pro) and a cellular activity are required for the degradation of p53 observed in cells infected with poliovirus.

Inhibition of host RNA polymerase II-dependent transcription by vesicular stomatitis virus results from inactivation of TFIID

During infection with vesicular stomatitis virus (VSV), host-cell mRNA synthesis is inhibited due to shut off of host-cell transcription. The transcriptional activity of nuclear extracts prepared from VSV-infected cells was compared to the activity of nuclear extracts from uninfected cells. An exogenous DNA template was used which contained an adenovirus major late promoter (AdMLP) but lacked upstream activating sequences, so that only basal transcription activity was assayed in these experiments. AdMLP-initiated transcription was decreased by 75% in nuclear extracts from infected cells as early as 3 h p.i. and by >90% by 6 h p.i. Mixing nuclear extracts from uninfected and VSV-infected cells revealed that the inhibition was caused by lack of an active form of a host factor involved in basal transcription rather than by the presence of an excess of inhibitory factor. To determine which transcription factors were lacking from nuclear extracts of infected cells, host transcription initiation factors isolated from uninfected cells by ion-exchange chromatography were added separately to nuclear extracts inactivated by VSV infection. A phosphocellulose column fraction from uninfected cells eluted with 0. 8 M KCl, which contained transcription factor IID (TFIID), overcame the inhibition. The corresponding fraction from infected cells had no detectable activity in a TFIID-dependent in vitro transcription assay. TATA-binding protein (TBP) is the DNA-binding subunit of TFIID and has been shown previously to substitute for TFIID in basal transcription. Purified recombinant TBP also reconstituted the transcription activity of nuclear extracts from infected cells, supporting the idea that TFIID is the target of virus-induced inhibition. Western blot analysis showed that the level of TBP in nuclear extracts or in the 0.8 M KCl column fraction was not changed by VSV infection. These results indicated that VSV infection leads to an inhibition of host transcription by inactivation of TFIID rather than reduction in the level of TFIID.

Cleavage of transcriptional activator Oct-1 by poliovirus encoded protease 3Cpro

In HeLa cells, RNA polymerase II mediated transcription is severely inhibited by poliovirus infection. Both basal and activated transcription are affected to bring about a complete shutoff of host cell transcription. We demonstrate here that the octamer binding transcription factor, Oct-1, is cleaved in HeLa cells infected with poliovirus. Incubation of Oct-1 with the purified, recombinant 3Cpro results in the generation of the cleaved Oct-1 product seen in virus infected cells. Poliovirus infection leads to the formation of altered Oct-1 DNA complexes that can also be generated by incubation of Oct-1 with purified 3Cpro. We also show that Oct-1 cleaved by 3Cpro loses its ability to inhibit transcriptional activation by the SV40 B enhancer. These results suggest that cleavage of Oct-1 in poliovirus infected cells leads to the loss of its activity.

Poliovirus proteinase 3C converts an active form of transcription factor IIIC to an inactive form: a mechanism for inhibition of host cell polymerase III transcription by poliovirus

In HeLa cells, RNA polymerase III (pol III)-mediated transcription is severely inhibited by poliovirus infection. This is due primarily to a reduction in the transcriptional activity of TFIIIC, a transcription factor which binds in a sequence specific manner to the internal promoter of pol III genes. Using gel retardation assays, we have shown previously that inhibition of pol III transcription by poliovirus is correlated with disappearance of a transcriptionally active form of TFIIIC (complex I) concomitant with the appearance of a faster mobility, transcriptionally inactive form of TFIIIC (complex III). We show here that a poliovirus with a point mutation in the proteinase 3C (3Cpro) region failed to produce complex III and is limited in its ability to inhibit pol III transcription compared with the wild-type virus. Incubation of purified 3Cpro, expressed in Escherichia coli, with transcriptionally active TFIIIC (complex I) in vitro resulted in generation of the transcriptionally inactive complex III form of TFIIIC. In an in vitro transcription assay, treatment of the complex I form of TFIIIC with 3Cpro almost completely inhibited pol III transcription. Finally expression of the 3Cpro gene in transfected HeLa cells resulted in significant inhibition of pol III-mediated transcription. The results presented here suggest that proteolysis of the transcriptionally active form of TFIIIC by poliovirus 3Cpro is a mechanism by which poliovirus inhibits host cell RNA pol III transcription.

Foot-and-mouth disease virus protease 3C inhibits cellular transcription and mediates cleavage of histone H3

Foot-and-mouth disease virus protease 3C is essential for the processing of the viral precursor polyprotein. It is shown here to also inhibit gene expression in baby hamster kidney cells after transient expression from transfected cDNA fragments. Protease 3C could not be detected by indirect immunofluorescence in contrast to other cDNA-encoded virus proteins, but protein synthesized de novo 16 hr after transfection could be detected by radioimmunoprecipitation. The cellular translation apparatus was, therefore, not inhibited. The enzyme, although produced as part of a fusion protein, was in size indistinguishable from that found in virus-infected cells. This suggested that the enzyme was released by autocatalysis from the recombinant fusion protein and from viral precursor protein in a similar manner. Transcription of protease 3C-encoding cDNA fragments as well as that of cotransfected fragments, which do not encode protease 3C, was inhibited as determined by hybridization assays. The shut off of transcription which was one of the cytopathic effects observed in virus-infected cells therefore correlates with the production of transactive protease 3C. The inhibitory molecular mechanism may involve truncation of the nuclear protein histone H3 at its N-terminus since this protein was found similarly truncated in virus-infected cells and after transfer of 3C-encoding cDNA fragments.