Phosphatidylinositol‐4 kinase III beta and oxysterol‐binding protein accumulate unesterified cholesterol on poliovirus‐induced membrane structure

Studies on anti‐picornavirus compounds have revealed an essential role of a novel cellular pathway via host phosphatidylinositol‐4 kinase III beta (PI4KB) and oxysterol‐binding protein (OSBP) family I in poliovirus (PV) replication. However, the molecular role for this pathway in PV replication has yet to be determined. Here, viral and host proteins modulating production of phosphatidylinositol 4‐phosphate (PI4P) and accumulation of unesterified cholesterol (UC) in cells were analyzed and the role of the PI4KB/OSBP pathway in PV replication characterized. Virus protein 2BC was identified as a novel interactant of PI4KB. PI4KB and VCP/p97 bind to a partially overlapped region of 2BC with different sensitivity to a 2C inhibitor. Production of PI4P and accumulation of UC were enhanced by virus protein 2BC, but suppressed by virus proteins 3A and 3AB. In PV‐infected cells, a PI4KB inhibitor suppressed production of PI4P, and both a PI4KB inhibitor and an OSBP ligand suppressed accumulation of UC on virus‐induced membrane structure. Inhibition of PI4KB activity caused dissociation of OSBP from virus‐induced membrane structure in PV‐infected cells. Synthesis of viral nascent RNA in PV‐infected cells was not affected in the presence of PI4KB inhibitor and OSBP ligand; however, transient pre‐treatment of PV‐infected cells with these inhibitors suppressed viral RNA synthesis. These results suggest that virus proteins modulate PI4KB activity and provide PI4P for recruitment of OSBP to accumulate UC on virus‐induced membrane structure for formation of a virus replication complex.     

Tyrosine 3 of poliovirus terminal peptide VPg(3B) has an essential function in RNA replication in the context of its precursor protein, 3AB

Poliovirus (PV) VPg is a genome-linked protein that is essential for the initiation of viral RNA replication. It has been well established that RNA replication is initiated when a molecule of UMP is covalently linked to the hydroxyl group of a tyrosine (Y3) in VPg by the viral RNA polymerase 3D(pol), but it is not yet known whether the substrate for uridylylation in vivo is the free peptide itself or one of its precursors. The aim of this study was to use complementation analyses to obtain information about the true in vivo substrate for uridylylation by 3D(pol). Previously, it was shown that a VPg mutant, in which tyrosine 3 and threonine 4 were replaced by phenylalanine and alanine (3F4A), respectively, was nonviable. We have now tested whether wild-type forms of proteins 3B, 3BC, 3BCD, 3AB, 3ABC, and P3 provided either in trans or in cis could rescue the replication defect of the VPg(3F4A) mutations in the PV polyprotein. Our results showed that proteins 3B, 3BC, 3BCD, and P3 were unable to complement the RNA replication defect in dicistronic PV or dicistronic luciferase replicons in vivo. However, cotranslation of the P3 precursor protein allowed rescue of RNA replication of the VPg(3F4A) mutant in an in vitro cell-free translation-RNA replication system, but only poor complementation was observed when 3BC, 3AB, 3BCD, or 3ABC proteins were cotranslated in the same assay. Interestingly, only protein 3AB but not 3B and 3BC, when provided in cis by insertion of a wild-type 3AB coding sequence between the P2 and P3 domains of the polyprotein, supported the replication of the mutated genome in vivo. Elimination of cleavage between 3A and 3B in the complementing 3AB protein, however, led to a complete lack of RNA replication. Our results suggest that (i) VPg has to be delivered to the replication complex in the form of a large protein precursor (P3) to be fully functional in replication; (ii) the replication complex formed during PV replication in vivo is essentially inaccessible to proteins provided in trans, even if the complementing protein is translated from a different cistron of the same RNA genome; (iii) 3AB is the most likely precursor of VPg; and (iv) Y3 of VPg has an essential function in RNA replication in the context of both VPg and 3AB.     

Intracellular topology and epitope shielding of poliovirus 3A protein

The poliovirus RNA replication complex comprises multiple viral and possibly cellular proteins assembled on the cytoplasmic surface of rearranged intracellular membranes. Viral proteins 3A and 3AB perform several functions during the poliovirus replicative cycle, including significant roles in rearranging membranes, anchoring the viral polymerase to these membranes, inhibiting host protein secretion, and possibly providing the 3B protein primer for RNA synthesis. During poliovirus infection, the immunofluorescence signal of an amino-terminal epitope of 3A-containing proteins is markedly shielded compared to 3A protein expressed in the absence of other poliovirus proteins. This is not due to luminal orientation of all or a subset of the 3A-containing polypeptides, as shown by immunofluorescence following differential permeabilization and proteolysis experiments. Shielding of the 3A epitope is more pronounced in cells infected with wild-type poliovirus than in cells with temperature-sensitive mutant virus that contains a mutation in the 3D polymerase coding region adjacent to the 3AB binding site. Therefore, it is likely that direct binding of the poliovirus RNA-dependent RNA polymerase occludes the amino terminus of 3A-containing polypeptides in the RNA replication complex.     

Genetic dissection of interaction between poliovirus 3D polymerase and viral protein 3AB.

Poliovirus RNA-dependent RNA polymerase 3D and viral protein 3AB are both thought to be required for the initiation of RNA synthesis. These two proteins physically associate with each other and with viral RNA replication complexes found on virus-induced membranes in infected cells. An understanding of the interface between 3D and 3AB would provide a first step in visualizing the architecture of the multiprotein complex that is assembled during poliovirus infection to replicate and package the viral RNA genome. The identification of mutations in 3D that diminish 3D-3AB interactions without affecting other functions of 3D polymerase is needed to study the function of the 3D-3AB interaction in infected cells. We describe the use of the yeast two-hybrid system to isolate and characterize mutations in 3D polymerase that cause it to interact less efficiently with 3AB than wild-type polymerase. One mutation, a substitution of leucine for valine at position 391 (V391L), resulted in a 3AB-specific interaction defect in the two-hybrid system, causing a reduction in the interaction of 3D polymerase with 3AB but not with another viral protein or a host protein tested. In vitro, purified 3D-V391L polymerase bound to membrane-associated 3AB with reduced affinity. Poliovirus that contained the 3D-V391L mutation was temperature sensitive, displaying a pronounced conditional defect in RNA synthesis. We conclude that interaction between 3AB and 3D or 3D-containing polypeptides plays a role in RNA synthesis during poliovirus infection.     

Viability of poliovirus/rhinovirus VPg chimeric viruses and identification of an amino acid residue in the VPg gene critical for viral RNA replication

Picornaviral RNA replication utilizes a small virus-encoded protein, termed 3B or VPg, as a primer to initiate RNA synthesis. This priming step requires uridylylation of the VPg peptide by the viral polymerase protein 3D(pol), in conjunction with other viral or host cofactors. In this study, we compared the viral specificity in 3D(pol)-catalyzed uridylylation reactions between poliovirus (PV) and human rhinovirus 16 (HRV16). It was found that HRV16 3D(pol) was able to uridylylate PV VPg as efficiently as its own VPg, but PV 3D(pol) could not uridylylate HRV16 VPg. Two chimeric viruses, PV containing HRV16 VPg (PV/R16-VPg) and HRV16 containing PV VPg (R16/PV-VPg), were constructed and tested for replication capability in H1-HeLa cells. Interestingly, only PV/R16-VPg chimeric RNA produced infectious virus particles upon transfection. No viral RNA replication or cytopathic effect was observed in cells transfected with R16/PV-VPg chimeric RNA, despite the ability of HRV16 3D(pol) to uridylylate PV VPg in vitro. Sequencing analysis of virion RNA isolated from the virus particles generated by PV/R16-VPg chimeric RNA identified a single residue mutation in the VPg peptide (Glu(6) to Val). Reverse genetics confirmed that this mutation was highly compensatory in enhancing replication of the chimeric viral RNA. PV/R16-VPg RNA carrying this mutation replicated with similar kinetics and magnitude to wild-type PV RNA. This cell culture-induced mutation in HRV16 VPg moderately increased its uridylylation by PV 3D(pol) in vitro, suggesting that it might be involved in other function(s) in addition to the direct uridylylation reaction. This study demonstrated the use of chimeric viruses to characterize viral specificity and compatibility in vivo between PV and HRV16 and to identify critical amino acid residue(s) for viral RNA replication.     

Towards an understanding of the poliovirus replication complex: the solution structure of the soluble domain of the poliovirus 3A protein

Poliovirus is a positive-strand RNA virus and the prototypical member of the Picornaviridae family. Upon infection, the viral RNA genome is translated from a single open reading frame into a polypeptide which undergoes a series of cleavages to ultimately form four structural and seven non-structural proteins. A replication complex is then formed which replicates the viral genome into negative and positive strands for further translation, replication, and packaging into viral progeny. Poliovirus 3A protein (3A) is a critical component of the viral replication complex and is the putative target of enviroxime, an antiviral drug shown to block viral replication. 3A also inhibits host cell endoplasmic reticulum-to-Golgi apparatus transport, a function which may play a key role in viral evasion from the host immune response. 3A, an 87-residue protein consisting of a soluble N terminus and a hydrophobic C terminus, is formed by the cleavage of the precursor protein 3AB into 3A and 3B (VPg). Although they differ by only 22 residues, the precursor protein 3AB and its cleavage product 3A have distinct functions in viral replication. We have determined the structure of the soluble, N-terminal domain of 3A (3A-N) using NMR spectroscopy. We show that 3A-N exists as a symmetric dimer, and each monomer consists of an alpha-helical hairpin with unstructured, yet functional, N- and C termini. We also show that the 3A-N structure contains a negatively charged surface patch and provides a context for interpreting the biochemical characteristics of a number of previously reported 3A and 3AB mutants.     

Initiation of poliovirus negative-strand RNA synthesis requires precursor forms of p2 proteins

The replication proteins encoded in the P2 region of the poliovirus genome induce extensive rearrangement of cellular membranes into vesicles and are a required component of viral RNA replication complexes. To identify distinct viral protein(s) from the P2 region of the genome that were required to form functional RNA replication complexes, the P2 proteins were expressed in addition to P3 in HeLa S10 translation-RNA replication reactions. Membrane-associated preinitiation replication complexes were isolated from these reactions and used to measure negative-strand synthesis. The formation of replication complexes capable of initiating negative-strand synthesis was observed when either P23 or when P2 and P3 were expressed in the HeLa S10 translation-replication reactions. The amount of negative-strand RNA synthesized with P2 and P3 was approximately 50% of that observed with P23. Negative-strand synthesis was not observed when the processed forms of the P2 proteins (e.g., 2A, 2B, 2C, 2AB, and 2BC) were used in various combinations in place of P2. In contrast, the expression of 2A and 2BCP3 supported negative-strand synthesis at the same level observed with P23. Therefore, functional replication complexes were formed in reaction mixtures that contained either 2A and 2BCP3 or P2 and P3. Genetic complementation analysis of P23 RNA that contained a lethal mutation in 2C confirmed these results. The expression of 2BCP3 in trans restored the replication of P23-2C(P131N) RNA to wild-type levels. The expression of P2 and P3 also complemented the replication of this mutant RNA, although very inefficiently. Complementation was not observed in reactions that contained P2 alone, 2BC, or 2C. Based on these results, we propose that RNA replication complexes are initially formed with the primary cleavage products of P23 (i.e., P2 and P3 or 2A and 2BCP3), and that 2A and 2BCP3 are preferentially used in this process.     

Inefficient complementation activity of poliovirus 2C and 3D proteins for rescue of lethal mutations.

Poliovirus (PV) 2C protein is a nonstructural polypeptide involved in viral RNA replication, whose biochemical activity(ies) in this process has not been defined. By using site-directed mutagenesis, it was shown previously that disruption of nucleotide-binding motifs present in this protein abolished viral RNA synthesis (C. Mirzayan and E. Wimmer, Virology 189:547-555, 1992; N. L. Teterina, K. M. Kean, E. Gorbalenya, V. I. Agol, and M. Girard, J. Gen. Virol. 73:1977-1986, 1992). We have tested whether PV 2C or 2BC protein provided in trans could rescue the replication of these mutated genomes. Rescuing proteins were provided either by cotransfection with helper chimeric PV-coxsackievirus genomes or by expression in cells with a vaccinia virus-T7 RNA polymerase transient-expression system. We report here that replication of mutated RNAs genomes was poorly supported in trans both by helper genomes and by expressed 2C or 2BC proteins. Similarly, very inefficient complementation was observed for two mutated genomes with lethal lesions in 3D polymerase coding sequence. Our results indicate that poliovirus RNA replication shows marked preference for proteins contributed in cis.     

cis-acting lesions targeted to the hydrophobic domain of a poliovirus membrane protein involved in RNA replication.

The structural requirements of the hydrophobic domain contained in poliovirus polypeptide 3AB were studied by using a molecular genetic approach in combination with an in vitro biochemical analysis. We report here the generation and analysis of deletion, insertion, and amino acid replacement mutations aimed at decreasing the hydrophobic character of the domain. Our results indicated that the hydrophobicity of this region of 3AB is necessary to maintain normal viral RNA synthesis. However, in vitro membrane association assays of the mutated proteins did not establish a direct correlation between 3AB membrane association and viral RNA synthesis. Some of the lethal mutations we engineered produced polyproteins with abnormal P2- and P3-processing capabilities due to an alteration in the normal cleavage order of the polyprotein. A detailed analysis of these mutants suggests that P2 is not the major precursor for polypeptides 2A and 2BC and that P2 protein products are derived from P2-P3-containing precursors (most likely P2-P3 or P2-3AB). Such precursors are likely to result from primary polyprotein cleavage events that initiate a proteolytic cascade not previously documented. Our results also indicated that the function provided by the hydrophobic domain of 3AB cannot be provided in trans. We discuss the implications of these results on the formation of limited-diffusion replication complexes as a means of sequestering P2- and P3-region polypeptides required for RNA synthesis and protein processing.     

A cysteine-rich motif in poliovirus protein 2C(ATPase) is involved in RNA replication and binds zinc in vitro

Protein 2C(ATPase) of picornaviruses is involved in the rearrangement of host cell organelles, viral RNA replication, and encapsidation. However, the biochemical and molecular mechanisms by which 2C(ATPase) engages in these processes are not known. To characterize functional domains of 2C(ATPase), we have focused on a cysteine-rich motif near the carboxy terminus of poliovirus 2C(ATPase). This region, which is well conserved among enteroviruses and rhinoviruses displaying an amino acid arrangement resembling zinc finger motifs, was studied by genetic and biochemical analyses. A mutation that replaced the first cysteine residue of the motif with a serine was lethal. A mutant virus which lacked the second of four potential coordination sites for zinc was temperature sensitive. At the restrictive temperature, RNA replication was inhibited whereas translation and polyprotein processing, assayed in vitro and in vivo, appeared to be normal. An intragenomic second-site revertant which reinserted the missing coordination site for zinc and recovered RNA replication at the restrictive temperature was isolated. The cysteine-rich motif was sufficient to bind zinc in vitro, as assessed in the presence of 4-(2-pyridylazo)resorcinol by a colorimetric assay. Zinc binding, however, was not required for hydrolysis of ATP. 2C(ATPase) as well as its precursors 2BC and P2 were found to exist in a reduced form in poliovirus-infected cells.     

The poliovirus replication machinery can escape inhibition by an antiviral drug that targets a host cell protein

Viral replication depends on specific interactions with host factors. For example, poliovirus RNA replication requires association with intracellular membranes. Brefeldin A (BFA), which induces a major rearrangement of the cellular secretory apparatus, is a potent inhibitor of poliovirus RNA replication. Most aspects governing the relationship between viral replication complex and the host membranes remain poorly defined. To explore these interactions, we used a genetic approach and isolated BFA-resistant poliovirus variants. Mutations within viral proteins 2C and 3A render poliovirus resistant to BFA. In the absence of BFA, viruses containing either or both of these mutations replicated similarly to wild type. In the presence of BFA, viruses carrying a single mutation in 2C or 3A exhibited an intermediate-growth phenotype, while the double mutant was fully resistant. The viral proteins 2C and 3A have critical roles in both RNA replication and vesicle formation. The identification of BFA resistant mutants may facilitate the identification of cellular membrane-associated proteins necessary for induction of vesicle formation and RNA replication. Importantly, our data underscore the dramatic plasticity of the host-virus interactions required for successful viral replication.     

ACBD3-mediated recruitment of PI4KB to picornavirus RNA replication sites

Phosphatidylinositol 4-kinase IIIβ (PI4KB) is a host factor required for genome RNA replication of enteroviruses, small non-enveloped viruses belonging to the family Picornaviridae. Here, we demonstrated that PI4KB is also essential for genome replication of another picornavirus, Aichi virus (AiV), but is recruited to the genome replication sites by a different strategy from that utilized by enteroviruses. AiV non-structural proteins, 2B, 2BC, 2C, 3A, and 3AB, interacted with a Golgi protein, acyl-coenzyme A binding domain containing 3 (ACBD3). Furthermore, we identified previously unknown interaction between ACBD3 and PI4KB, which provides a novel manner of Golgi recruitment of PI4KB. Knockdown of ACBD3 or PI4KB suppressed AiV RNA replication. The viral proteins, ACBD3, PI4KB, and phophatidylinositol-4-phosphate (PI4P) localized to the viral RNA replication sites. AiV replication and recruitment of PI4KB to the RNA replication sites were not affected by brefeldin A, in contrast to those in enterovirus infection. These results indicate that a viral protein/ACBD3/PI4KB complex is formed to synthesize PI4P at the AiV RNA replication sites and plays an essential role in viral RNA replication.     

The host protein required for in vitro replication of poliovirus is a protein kinase that phosphorylates eukaryotic initiation factor-2

The HeLa cell protein (host factor) required for in vitro replication of poliovirus has been identified as a 67,000 dalton phosphoprotein. The purified protein displays three activities in vitro: stimulation of poliovirus RNA synthesis in the presence of poliovirus replicase, apparent self-phosphorylation, and phosphorylation of the alpha-subunit of eukaryotic protein synthesis initiation factor 2 (eIF-2). All three activities can be removed or inhibited by an antibody to host factor. Partially purified preparations of reticulocyte eIF-2 contain a similar phosphoprotein and display host factor activity in the viral RNA synthesis assay in vitro. In vitro phosphorylation of the 67 kd protein can be stimulated by low concentrations of double-stranded RNA. Addition of phosphorylated host factor in an in vitro RNA synthesis assay significantly changes the kinetics of viral RNA synthesis, indicating that protein phosphorylation may play an important role in viral RNA replication.     

Analysis of poliovirus protein 3A interactions with viral and cellular proteins in infected cells

Poliovirus proteins 3A and 3AB are small, membrane-binding proteins that play multiple roles in viral RNA replication complex formation and function. In the infected cell, these proteins associate with other viral and cellular proteins as part of a supramolecular complex whose structure and composition are unknown. We isolated viable viruses with three different epitope tags (FLAG, hemagglutinin [HA], and c-myc) inserted into the N-terminal region of protein 3A. These viruses exhibited growth properties and characteristics very similar to those of the wild-type, untagged virus. Extracts prepared from the infected cells were subjected to immunoaffinity purification of the tagged proteins by adsorption to commercial antibody-linked beads and examined after elution for cellular and other viral proteins that remained bound to 3A sequences during purification. Viral proteins 2C, 2BC, 3D, and 3CD were detected in all three immunopurified 3A samples. Among the cellular proteins previously reported to interact with 3A either directly or indirectly, neither LIS1 nor phosphoinositol-4 kinase (PI4K) were detected in any of the purified tagged 3A samples. However, the guanine nucleotide exchange factor GBF1, which is a key regulator of membrane trafficking in the cellular protein secretory pathway and which has been shown previously to bind enteroviral protein 3A and to be required for viral RNA replication, was readily recovered along with immunoaffinity-purified 3A-FLAG. Surprisingly, we failed to cocapture GBF1 with 3A-HA or 3A-myc proteins. A model for variable binding of these 3A mutant proteins to GBF1 based on amino acid sequence motifs and the resulting practical and functional consequences thereof are discussed.     

Cellular protein modification by poliovirus: the two faces of poly(rC)-binding protein

During picornavirus infection, several cellular proteins are cleaved by virus-encoded proteinases. Such cleavage events are likely to be involved in the changing dynamics during the intracellular viral life cycle, from viral translation to host shutoff to RNA replication to virion assembly. For example, it has been proposed that there is an active switch from poliovirus translation to RNA replication mediated by changes in RNA-binding protein affinities. This switch could be a mechanism for controlling template selection for translation and negative-strand viral RNA synthesis, two processes that use the same positive-strand RNA as a template but proceed in opposing directions. The cellular protein poly(rC)-binding protein (PCBP) was identified as a primary candidate for regulating such a mechanism. Among the four different isoforms of PCBP in mammalian cells, PCBP2 is required for translation initiation on picornavirus genomes with type I internal ribosome entry site elements and also for RNA replication. Through its three K-homologous (KH) domains, PCPB2 forms functional protein-protein and RNA-protein complexes with components of the viral translation and replication machinery. We have found that the isoforms PCBP1 and -2 are cleaved during the mid-to-late phase of poliovirus infection. On the basis of in vitro cleavage assays, we determined that this cleavage event was mediated by the viral proteinases 3C/3CD. The primary cleavage occurs in the linker between the KH2 and KH3 domains, resulting in truncated PCBP2 lacking the KH3 domain. This cleaved protein, termed PCBP2-DeltaKH3, is unable to function in translation but maintains its activity in viral RNA replication. We propose that through the loss of the KH3 domain, and therefore loss of its ability to function in translation, PCBP2 can mediate the switch from viral translation to RNA replication.     

Activation of cellular Arf GTPases by poliovirus protein 3CD correlates with virus replication

We have previously shown that synthesis of poliovirus protein 3CD in uninfected HeLa cell extracts induces an increased association with membranes of the cellular Arf GTPases, which are key players in cellular membrane traffic. Arfs cycle between an inactive, cytoplasmic, GDP-bound form and an active, membrane-associated, GTP-bound form. 3CD promotes binding of Arf to membranes by initiating recruitment to membranes of guanine nucleotide exchange factors (GEFs), BIG1 and BIG2. GEFs activate Arf by replacing GDP with GTP. In poliovirus-infected cells, there is a dramatic redistribution of cellular Arf pools that coincides with the reorganization of membranes used to form viral RNA replication complexes. Here we demonstrate that Arf translocation in vitro can be induced by purified recombinant 3CD protein; thus, concurrent translation of viral RNA is not required. Coexpression of 3C and 3D proteins was not sufficient to target Arf to membranes. 3CD expressed in HeLa cells was retained after treatment of the cells with digitonin, indicating that it may interact with a membrane-bound host factor. A F441S mutant of 3CD was shown previously to have lost Arf translocation activity and was also defective in attracting the corresponding GEFs to membranes. A series of other mutations were introduced at 3CD residue F441. Mutations that retained Arf translocation activity of 3CD also supported efficient growth of virus, regardless of their effects on 3D polymerase elongation activity. Those that abrogated Arf activation by 3CD generated quasi-infectious RNAs that produced some plaques from which revertants that always restored the Arf activation property of 3CD were rescued.     

Stimulation of poliovirus synthesis in a HeLa cell-free in vitro translation-RNA replication system by viral protein 3CDpro

The plus-strand RNA genome of poliovirus serves three distinct functions in the life cycle of the virus. The RNA is translated and then replicated, and finally the progeny RNAs are encapsidated. These processes can be faithfully reproduced in a HeLa cell-free in vitro translation-RNA replication system that produces viable poliovirus. We have previously observed a stimulation of virus synthesis when an mRNA, encoding protein 3CD(pro), is added to the translation-RNA replication reactions of poliovirus RNA. Our aim in these experiments was to further define the factors that affect the stimulatory activity of 3CD(pro) in virus synthesis. We observed that purified 3CD(pro) protein also enhances virus synthesis by about 100-fold but has no effect on the translation of the polyprotein. Optimal stimulation is observed only when 3CD(pro) is present early in the incubation period. The stimulation, however, is abolished by a mutation either in the RNA binding domain of 3CD(pro), 3C(pro)R84S/I86A, or by each of two groups of complementary mutations R455A/R456A and D339A/S341A/D349A at interface I in the 3D(pol) domain of 3CD(pro). Surprisingly, virus synthesis is strongly inhibited by the addition of both 3C(pro) and 3CD(pro) at the beginning of incubation. We also examined the effect of other viral or cellular proteins on virus synthesis in the in vitro system. No enhancement of virus synthesis occurred with viral proteins 3BC, 3ABC, 3BCD, 3D(pol), and 3C(pro) or with cellular protein PCBP2. These results suggest that 3CD(pro) has to be present in the reaction at the time the replication complexes are assembled and that both the 3C(pro) and 3D(pol) domains of the protein are required for its activity that stimulates virus production.     

Molecular dissection of the multifunctional poliovirus RNA-binding protein 3AB.

Genome replication of poliovirus, as yet unsolved, involves numerous viral polypeptides that arise from proteolysis of the viral polyprotein. One of these proteins is 3AB, an RNA-binding protein with multiple functions, that serves also as the precursor for the genome-linked protein VPg (= 3B). Eight clustered charged amino acid-to-alanine mutants in the 3AB coding region of poliovirus were constructed and analyzed, together with three additional single-amino acid exchange mutants in VPg, for viral phenotypes. All mutants expressed severe inhibition in RNA synthesis, but none were temperature sensitive (ts). The 3AB polypeptides of mutants with a lethal phenotype were overexpressed in Escherichia coli, purified to near homogeneity, and studied with respect to four functions: (1) ribonucleoprotein complex formation with 3CDpro and the 5'-terminal cloverleaf of the poliovirus genome; (2) binding to the genomic and negative-sense RNA; (3) stimulation of 3CDpro cleavage; and (4) stimulation of RNA polymerase activity of 3Dpol. The results have allowed mapping of domains important for RNA binding and the formation of certain protein-protein complexes, and correlation of these processes with essential steps in viral genome replication.     

Complete replication of poliovirus in vitro: preinitiation RNA replication complexes require soluble cellular factors for the synthesis of VPg-linked RNA.

Translation of poliovirion RNA in HeLa S10 extracts resulted in the formation of RNA replication complexes which catalyzed the asymmetric replication of poliovirus RNA. Synthesis of poliovirus RNA was detected in unfractionated HeLa S10 translation reactions and in RNA replication complexes isolated from HeLa S10 translation reactions by pulse-labeling with [32P]CTP. The RNA replication complexes formed in vitro contained replicative-intermediate RNA and were enriched in viral protein 3CD and the membrane-associated viral proteins 2C, 2BC, and 3AB. Genome-length poliovirus RNA covalently linked to VPg was synthesized in large amounts by the replication complexes. RNA replication was highly asymmetric, with predominantly positive-polarity RNA products. Both anti-VPg antibody and guanidine HCl inhibited RNA replication and virus formation in the HeLa S10 translation reactions without affecting viral protein synthesis. The inhibition of RNA synthesis by guanidine was reversible. The reversible nature of guanidine inhibition was used to demonstrate the formation of preinitiation RNA replication complexes in reaction mixes containing 2 mM guanidine HCl. Preinitiation complexes sedimented upon centrifugation at 15,000 x g and initiated RNA replication upon their resuspension in reaction mixes lacking guanidine. Initiation of RNA synthesis by preinitiation complexes did not require active protein synthesis or the addition of soluble viral proteins. Initiation of RNA synthesis by preinitiation complexes, however, was absolutely dependent on soluble HeLa cytoplasmic factors. Preinitiation complexes also catalyzed the formation of infectious virus in reaction mixes containing exogenously added capsid proteins. The titer of infectious virus produced in such trans-encapsidation reactions reached 4 x 10(7) PFU/ml. The HeLa S10 translation-RNA replication reactions represent an efficient in vitro system for authentic poliovirus replication, including protein synthesis, polyprotein processing, RNA replication, and virus assembly.     

Modification of cellular autophagy protein LC3 by poliovirus

Poliovirus infection remodels intracellular membranes, creating a large number of membranous vesicles on which viral RNA replication occurs. Poliovirus-induced vesicles display hallmarks of cellular autophagosomes, including delimiting double membranes surrounding the cytosolic lumen, acquisition of the endosomal marker LAMP-1, and recruitment of the 18-kDa host protein LC3. Autophagy results in the covalent lipidation of LC3, conferring the property of membrane association to this previously microtubule-associated protein and providing a biochemical marker for the induction of autophagy. Here, we report that a similar modification of LC3 occurs both during poliovirus infection and following expression of a single viral protein, a stable precursor termed 2BC. Therefore, one of the early steps in cellular autophagy, LC3 modification, can be genetically separated from the induction of double-membraned vesicles that contain the modified LC3, which requires both viral proteins 2BC and 3A. The existence of viral inducers that promote a distinct aspect of the formation of autophagosome-like membranes both facilitates the dissection of this cellular process and supports the hypothesis that this branch of the innate immune response is directly subverted by poliovirus.