Poliovirus infection enhances the formation of two ribonucleoprotein complexes at the 3' end of viral negative-strand RNA

Structures and Functions of Viral 5' Non-Coding Genomic RNA Domain-I in Group-B Enterovirus Infections

Group-B enteroviruses (EV-B) are ubiquitous naked single-stranded positive RNA viral pathogens that are responsible for common acute or persistent human infections. Their genome is composed in the 5′ end by a non-coding region, which is crucial for the initiation of the viral replication and translation processes. RNA domain-I secondary structures can interact with viral or cellular proteins to form viral ribonucleoprotein (RNP) complexes regulating viral genomic replication, whereas RNA domains-II to -VII (internal ribosome entry site, IRES) are known to interact with cellular ribosomal subunits to initiate the viral translation process. Natural 5′ terminally deleted viral forms lacking some genomic RNA domain-I secondary structures have been described in EV-B induced murine or human infections. Recent in vitro studies have evidenced that the loss of some viral RNP complexes in the RNA domain-I can modulate the viral replication and infectivity levels in EV-B infections. Moreover, the disruption of secondary structures of RNA domain-I could impair viral RNA sensing by RIG-I (Retinoic acid inducible gene I) or MDA5 (melanoma differentiation-associated protein 5) receptors, a way to overcome antiviral innate immune response. Overall, natural 5′ terminally deleted viral genomes resulting in the loss of various structures in the RNA domain-I could be major key players of host–cell interactions driving the development of acute or persistent EV-B infections.

Picornaviruses and RNA Metabolism: Local and Global Effects of Infection

Due to the limiting coding capacity for members of the Picornaviridae family of positive-strand RNA viruses, their successful replication cycles require complex interactions with host cell functions. These interactions span from the down-modulation of many aspects of cellular metabolism to the hijacking of specific host functions used during viral translation, RNA replication, and other steps of infection by picornaviruses, such as human rhinovirus, coxsackievirus, poliovirus, foot-and-mouth disease virus, enterovirus D-68, and a wide range of other human and nonhuman viruses. Although picornaviruses replicate exclusively in the cytoplasm of infected cells, they have extensive interactions with host cell nuclei and the proteins and RNAs that normally reside in this compartment of the cell. This review will highlight some of the more recent studies that have revealed how picornavirus infections impact the RNA metabolism of the host cell posttranscriptionally and how they usurp and modify host RNA binding proteins as well as microRNAs to potentiate viral replication.

Human astroviruses: in silico analysis of the untranslated region and putative binding sites of cellular proteins

Human astrovirus (HAstV) constitutes a major cause of acute gastroenteritis in children. The viral 5' and 3' untranslated regions (UTR) have been involved in the regulation of several molecular mechanisms. However, in astrovirues have been less characterized. Here, we analyzed the secondary structures of the 5' and 3' UTR of HAstV, as well as their putative target sites that might be recognized by cellular factors. To our knowledge, this is the first bioinformatic analysis that predicts the HAstV 5' UTR secondary structure. The analysis showed that both the UTR sequence and secondary structure are highly conserved in all HAstVs analyzed, suggesting their regulatory role of viral activities. Notably, the UTRs of HAstVs contain putative binding sites for the serine/arginine-rich factors SRSF2, SRSF5, SRSF6, SRSF3, and the multifunctional hnRNPE2 protein. More importantly, putative binding sites for PTB were localized in single-stranded RNA sequences, while hnRNPE2 sites were localized in double-stranded sequence of the HAstV 5' and 3' UTR structures. These analyses suggest that the combination of SRSF proteins, hnRNPE2 and PTB described here could be involved in the maintenance of the secondary structure of the HAstVs, possibly allowing the recruitment of the replication complex that selects and recruits viral RNA replication templates.

Exploitation of nuclear functions by human rhinovirus, a cytoplasmic RNA virus

Protein production, genomic RNA replication, and virion assembly during infection by picornaviruses like human rhinovirus and poliovirus take place in the cytoplasm of infected human cells, making them the quintessential cytoplasmic pathogens. However, a growing body of evidence suggests that picornavirus replication is promoted by a number of host proteins localized normally within the host cell nucleus. To systematically identify such nuclear proteins, we focused on those that appear to re-equilibrate from the nucleus to the cytoplasm during infection of HeLa cells with human rhinovirus via quantitative protein mass spectrometry. Our analysis revealed a highly selective re-equilibration of proteins with known mRNA splicing and transport-related functions over nuclear proteins of all other functional classes. The multifunctional splicing factor proline and glutamine rich (SFPQ) was identified as one such protein. We found that SFPQ is targeted for proteolysis within the nucleus by viral proteinase 3CD/3C, and a fragment of SFPQ was shown to migrate to the cytoplasm at mid-to-late times of infection. Cells knocked down for SFPQ expression showed significantly reduced rhinovirus titers, viral protein production, and viral RNA accumulation, consistent with SFPQ being a pro-viral factor. The SFPQ fragment that moved into the cytoplasm was able to bind rhinovirus RNA either directly or indirectly. We propose that the truncated form of SFPQ promotes viral RNA stability or replication, or virion morphogenesis. More broadly, our findings reveal dramatic changes in protein compartmentalization during human rhinovirus infection, allowing the virus to systematically hijack the functions of proteins not normally found at its cytoplasmic site of replication.

We explored the dynamics of host cell protein relocalization from the nucleus to the cytoplasm during an infection by human rhinovirus using quantitative mass spectrometry, confocal imaging, and Western blot analysis. We discovered a highly selective re-equilibration of proteins with known mRNA splicing and transport-related functions, including splicing factor proline and glutamine rich (SFPQ). Using RNAi experiments and viral replication assays, we demonstrated that SFPQ is a pro-viral factor required for rhinovirus growth. Our studies provide new insights into how this cytoplasmic RNA virus is able to alter and hijack the functions of host proteins that normally reside in the nucleus.

Functional Consequences of RNA 5'-Terminal Deletions on Coxsackievirus B3 RNA Replication and Ribonucleoprotein Complex Formation

Group B coxsackieviruses are responsible for chronic cardiac infections. However, the molecular mechanisms by which the virus can persist in the human heart long after the signs of acute myocarditis have abated are still not completely understood. Recently, coxsackievirus B3 strains with 5'-terminal deletions in genomic RNAs were isolated from a patient suffering from idiopathic dilated cardiomyopathy, suggesting that such mutant viruses may be the forms responsible for persistent infection. These deletions lacked portions of 5' stem-loop I, which is an RNA secondary structure required for viral RNA replication. In this study, we assessed the consequences of the genomic deletions observed in vivo for coxsackievirus B3 biology. Using cell extracts from HeLa cells, as well as transfection of luciferase replicons in two types of cardiomyocytes, we demonstrated that coxsackievirus RNAs harboring 5' deletions ranging from 7 to 49 nucleotides in length can be translated nearly as efficiently as those of wild-type virus. However, these 5' deletions greatly reduced the synthesis of viral RNA in vitro, which was detected only for the 7- and 21-nucleotide deletions. Since 5' stem-loop I RNA forms a ribonucleoprotein complex with cellular and viral proteins involved in viral RNA replication, we investigated the binding of the host cell protein PCBP2, as well as viral protein 3CD^pro, to deleted positive-strand RNAs corresponding to the 5' end. We found that binding of these proteins was conserved but that ribonucleoprotein complex formation required higher PCBP2 and 3CD^pro concentrations, depending on the size of the deletion. Overall, this study confirmed the characteristics of persistent CVB3 infection observed in heart tissues and provided a possible explanation for the low level of RNA replication observed for the 5'-deleted viral genomes-a less stable ribonucleoprotein complex formed with proteins involved in viral RNA replication.IMPORTANCE Dilated cardiomyopathy is the most common indication for heart transplantation worldwide, and coxsackie B viruses are detected in about one-third of idiopathic dilated cardiomyopathies. Terminal deletions at the 5' end of the viral genome involving an RNA secondary structure required for RNA replication have been recently reported as a possible mechanism of virus persistence in the human heart. These mutations are likely to disrupt the correct folding of an RNA secondary structure required for viral RNA replication. In this report, we demonstrate that transfected RNAs harboring 5'-terminal sequence deletions are able to direct the synthesis of viral proteins, but not genomic RNAs, in human and murine cardiomyocytes. Moreover, we show that the binding of cellular and viral replication factors to viral RNA is conserved despite genomic deletions but that the impaired RNA synthesis associated with terminally deleted viruses could be due to destabilization of the ribonucleoprotein complexes formed.

Generation of Recombinant Polioviruses Harboring RNA Affinity Tags in the 5' and 3' Noncoding Regions of Genomic RNAs

Despite being intensely studied for more than 50 years, a complete understanding of the enterovirus replication cycle remains elusive. Specifically, only a handful of cellular proteins have been shown to be involved in the RNA replication cycle of these viruses. In an effort to isolate and identify additional cellular proteins that function in enteroviral RNA replication, we have generated multiple recombinant polioviruses containing RNA affinity tags within the 3' or 5' noncoding region of the genome. These recombinant viruses retained RNA affinity sequences within the genome while remaining viable and infectious over multiple passages in cell culture. Further characterization of these viruses demonstrated that viral protein production and growth kinetics were unchanged or only slightly altered relative to wild type poliovirus. However, attempts to isolate these genetically-tagged viral genomes from infected cells have been hindered by high levels of co-purification of nonspecific proteins and the limited matrix-binding efficiency of RNA affinity sequences. Regardless, these recombinant viruses represent a step toward more thorough characterization of enterovirus ribonucleoprotein complexes involved in RNA replication.

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.

Initiation of protein-primed picornavirus RNA synthesis

Plus strand RNA viruses use different mechanisms to initiate the synthesis of their RNA chains. The Picornaviridae family constitutes a large group of plus strand RNA viruses that possess a small terminal protein (VPg) covalently linked to the 5'-end of their genomes. The RNA polymerases of these viruses use VPg as primer for both minus and plus strand RNA synthesis. In the first step of the initiation reaction the RNA polymerase links a UMP to the hydroxyl group of a tyrosine in VPg using as template a cis-replicating element (cre) positioned in different regions of the viral genome. In this review we will summarize what is known about the initiation reaction of protein-primed RNA synthesis by the RNA polymerases of the Picornaviridae. As an example we will use the RNA polymerase of poliovirus, the prototype of Picornaviridae. We will also discuss models of how these nucleotidylylated protein primers might be used, together with viral and cellular replication proteins and other cis-replicating RNA elements, during minus and plus strand RNA synthesis.

The structural and phylogenetic profile of the 3' terminus of coxsackievirus B3 negative strand

In the replication process of RNA(+) viruses both the positive-strand template and the newly synthesized negative strand appear in a double-stranded form, RF. It has been shown for poliovirus that prior to the initiation of positive-strand synthesis, the 5'-terminus of the positive strand must adopt a cloverleaf structure. When that happens, the 3'-terminal region of the negative strand is released from the RF form and is able to form into its own defined structure. In order to determine the secondary structure of this region, a comprehensive approach consisting of experimental mapping methods, phylogenetic analysis and computer predictions was applied. Here we propose the first structural model of the 3'-terminal region of the coxsackievirus B3 (CV-B3) negative strand, approximately 450 nucleotides in length. The region folds into three highly defined structural domains, I'-III'. The most 3'-terminal part of this region is domain I', which folds into a cloverleaf structure similar to that found in the viral RNA strand of positive-polarity. Remarkably, this motif is conserved among all analyzed viral isolates of CV-B3 despite the observed sequence diversity. Several other conserved structural motifs within the 3'-terminal region of the viral negative strand were also identified. The structure of this region may be crucial for the replication complex assembly.

Picornavirus modification of a host mRNA decay protein

Due to the limited coding capacity of picornavirus genomic RNAs, host RNA binding proteins play essential roles during viral translation and RNA replication. Here we describe experiments suggesting that AUF1, a host RNA binding protein involved in mRNA decay, plays a role in the infectious cycle of picornaviruses such as poliovirus and human rhinovirus. We observed cleavage of AUF1 during poliovirus or human rhinovirus infection, as well as interaction of this protein with the 5' noncoding regions of these viral genomes. Additionally, the picornavirus proteinase 3CD, encoded by poliovirus or human rhinovirus genomic RNAs, was shown to cleave all four isoforms of recombinant AUF1 at a specific N-terminal site in vitro. Finally, endogenous AUF1 was found to relocalize from the nucleus to the cytoplasm in poliovirus-infected HeLa cells to sites adjacent to (but distinct from) putative viral RNA replication complexes.

IMPORTANCE

This study derives its significance from reporting how picornaviruses like poliovirus and human rhinovirus proteolytically cleave a key player (AUF1) in host mRNA decay pathways during viral infection. Beyond cleavage of AUF1 by the major viral proteinase encoded in picornavirus genomes, infection by poliovirus results in the relocalization of this host cell RNA binding protein from the nucleus to the cytoplasm. The alteration of both the physical state of AUF1 and its cellular location illuminates how small RNA viruses manipulate the activities of host cell RNA binding proteins to ensure a faithful intracellular replication cycle.

Mechanistic intersections between picornavirus translation and RNA replication

Members of the Picornaviridae are positive-strand RNA viruses whose genomes contain internal ribosome entry sites (IRESs) in the 5' noncoding region (NCR). These viruses must utilize host cell factors for translation initiation and RNA replication in the cytoplasm of infected cells. Such cytoplasmic, positive-strand RNA viruses have a conflict between the processes of translation and negative-strand RNA synthesis, since they occur in opposing directions and utilize positive-strand viral RNA as a template. The most extensively studied picornavirus, poliovirus, will be the focus of this review. Critical RNA elements and factors involved in the virus replication cycle will be discussed, with an overview on how these steps in replication relate to the switch mechanism between IRES-dependent translation and synthesis of negative-strand RNA intermediates.

Direct inhibition of tombusvirus plus-strand RNA synthesis by a dominant negative mutant of a host metabolic enzyme, glyceraldehyde-3-phosphate dehydrogenase, in yeast and plants

The replication of plus-strand RNA viruses depends on many cellular factors. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is an abundant metabolic enzyme that is recruited to the replicase complex of Tomato bushy stunt virus (TBSV) and affects asymmetric viral RNA synthesis. To further our understanding on the role of GAPDH in TBSV replication, we used an in vitro TBSV replication assay based on recombinant p33 and p92(pol) viral replication proteins and cell-free yeast extract. We found that the addition of purified recombinant GAPDH to the cell extract prepared from GAPDH-depleted yeast results in increased plus-strand RNA synthesis and asymmetric production of viral RNAs. Our data also demonstrate that GAPDH interacts with p92(pol) viral replication protein, which may facilitate the recruitment of GAPDH into the viral replicase complex in the yeast model host. In addition, we have identified a dominant negative mutant of GAPDH, which inhibits RNA synthesis and RNA recruitment in vitro. Moreover, this mutant also exhibits strong suppression of tombusvirus accumulation in yeast and in virus-infected Nicotiana benthamiana. Overall, the obtained data support the model that the co-opted GAPDH plays a direct role in TBSV replication by stimulating plus-strand synthesis by the viral replicase.

Diverse roles of host RNA binding proteins in RNA virus replication

Plus-strand +RNA viruses co-opt host RNA-binding proteins (RBPs) to perform many functions during viral replication. A few host RBPs have been identified that affect the recruitment of viral +RNAs for replication. Other subverted host RBPs help the assembly of the membrane-bound replicase complexes, regulate the activity of the replicase and control minus- or plus-strand RNA synthesis. The host RBPs also affect the stability of viral RNAs, which have to escape cellular RNA degradation pathways. While many host RBPs seem to have specialized functions, others participate in multiple events during infection. Several conserved RBPs, such as eEF1A, hnRNP proteins and Lsm 1-7 complex, are co-opted by evolutionarily diverse +RNA viruses, underscoring some common themes in virus-host interactions. On the other hand, viruses also hijack unique RBPs, suggesting that +RNA viruses could utilize different RBPs to perform similar functions. Moreover, different +RNA viruses have adapted unique strategies for co-opting unique RBPs. Altogether, a deeper understanding of the functions of the host RBPs subverted for viral replication will help development of novel antiviral strategies and give new insights into host RNA biology.

An RNA element at the 5'-end of the poliovirus genome functions as a general promoter for RNA synthesis

RNA structures present throughout RNA virus genomes serve as scaffolds to organize multiple factors involved in the initiation of RNA synthesis. Several of these RNA elements play multiple roles in the RNA replication pathway. An RNA structure formed around the 5′- end of the poliovirus genomic RNA has been implicated in the initiation of both negative- and positive-strand RNA synthesis. Dissecting the roles of these multifunctional elements is usually hindered by the interdependent nature of the viral replication processes and often pleiotropic effects of mutations. Here, we describe a novel approach to examine RNA elements with multiple roles. Our approach relies on the duplication of the RNA structure so that one copy is dedicated to the initiation of negative-strand RNA synthesis, while the other mediates positive-strand synthesis. This allows us to study the function of the element in promoting positive-strand RNA synthesis, independently of its function in negative-strand initiation. Using this approach, we demonstrate that the entire 5′-end RNA structure that forms on the positive-strand is required for initiation of new positive-strand RNAs. Also required to initiate positive-strand RNA synthesis are the binding sites for the viral polymerase precursor, 3CD, and the host factor, PCBP. Furthermore, we identify specific nucleotide sequences within “stem a” that are essential for the initiation of positive-strand RNA synthesis. These findings provide direct evidence for a trans-initiation model, in which binding of proteins to internal sequences of a pre-existing positive-strand RNA affects the synthesis of subsequent copies of that RNA, most likely by organizing replication factors around the initiation site.

Enteroviruses are a subfamily of small, pathogenic, icosahedral viruses called picornaviruses. Poliovirus, the etiologic agent of paralytic poliomyelitis, is one of the most extensively studied members of this family. Poliovirus RNA replication utilizes a mechanism, common to all positive, single-stranded, lytic RNA viruses, which permits the amplification of a single initial molecule of RNA into thousands of RNA progeny in only a few hours. After entry, the viral genomic RNA is transcribed to generate a complementary RNA (negative-strand), which, in turn, is used as a template to synthesize new strands of genomic RNA (positive-strand). The specificity of the viral RNA template, and the relationship between translation and replication, are controlled by RNA elements present throughout the genome. Individual elements often carry out multiple, interdependent tasks, complicating the dissection of their precise roles in specific steps of replication. We employed a novel approach to overcome this roadblock. Our strategy demonstrated that an RNA element present at the 5′ end of the virus genome is the master regulator of the initiation of RNA synthesis.

Delayed kinetics of poliovirus RNA synthesis in a human cell line with reduced levels of hnRNP C proteins

The hnRNP C heterotetramer [(C1₃)C2] binds RNA polymerase II transcripts in the nucleus, along with other proteins of the core hnRNP complex, and plays an important role in mRNA biogenesis and transport. Infection of HeLa cells with poliovirus causes hnRNP C to re-localize from the nucleus, where it is normally retained during interphase, to the cytoplasm. We have proposed that in the cytoplasm, the protein isoforms of hnRNP C participate in the recognition of viral specific RNAs by the poliovirus replication proteins and/or in the assembly of membrane-bound RNA replication complexes. In SK-OV-3 cells, which express reduced levels of hnRNP C compared to HeLa cells or 293 cells, the kinetics of poliovirus replication are delayed. hnRNP C is also re-localized from the nucleus to the cytoplasm in SK-OV-3 cells infected with poliovirus. Increased expression of hnRNP C in SK-OV-3 cells by transient transfection increases the rate of virus production and overall yield over that seen in mock-transfected cells. We propose that hnRNP C interacts with poliovirus RNA and replication proteins to increase the efficiency of viral genomic RNA synthesis.

Mechanistic consequences of hnRNP C binding to both RNA termini of poliovirus negative-strand RNA intermediates

The poliovirus 3' noncoding region (3' NCR) is necessary for efficient virus replication. A poliovirus mutant, PVDelta3'NCR, with a deletion of the entire 3' NCR, yielded a virus that was capable of synthesizing viral RNA, albeit with a replication defect caused by deficient positive-strand RNA synthesis compared to wild-type virus. We detected multiple ribonucleoprotein (RNP) complexes in extracts from poliovirus-infected HeLa cells formed with a probe corresponding to the 5' end of poliovirus negative-strand RNA (the complement of the genomic 3' NCR), and the levels of these RNP complexes increased during the course of viral infection. Previous studies have identified RNP complexes formed with the 3' end of poliovirus negative-strand RNA, including one that contains a 36-kDa protein later identified as heterogeneous nuclear ribonucleoprotein C (hnRNP C). We report here that the 5' end of poliovirus negative-strand RNA is capable of interacting with endogenous hnRNP C, as well as with poliovirus nonstructural proteins. Further, we demonstrate that the addition of recombinant purified hnRNP C proteins can stimulate virus RNA synthesis in vitro and that depletion of hnRNP C proteins in cultured cells results in decreased virus yields and a correspondingly diminished accumulation of positive-strand RNAs. We propose that the association of hnRNP C with poliovirus negative-strand termini acts to stabilize or otherwise promote efficient positive-strand RNA synthesis.

Cis-acting RNA elements in human and animal plus-strand RNA viruses

The RNA genomes of plus-strand RNA viruses have the ability to form secondary and higher-order structures that contribute to their stability and to their participation in inter- and intramolecular interactions. Those structures that are functionally important are called cis-acting RNA elements because their functions cannot be complemented in trans. They can be involved not only in RNA/RNA interactions but also in binding of viral and cellular proteins during the complex processes of translation, RNA replication and encapsidation. Most viral cis-acting RNA elements are located in the highly structured 5'- and 3'-nontranslated regions of the genomes but sometimes they also extend into the adjacent coding sequences. In addition, some cis-acting RNA elements are embedded within the coding sequences far away from the genomic ends. Although the functional importance of many of these structures has been confirmed by genetic and biochemical analyses, their precise roles are not yet fully understood. In this review we have summarized what is known about cis-acting RNA elements in nine families of human and animal plus-strand RNA viruses with an emphasis on the most thoroughly characterized virus families, the Picornaviridae and Flaviviridae.

Host Factors Promoting Viral RNA Replication

Plus-stranded RNA viruses, the largest group among eukaryotic viruses, are capable of reprogramming host cells by subverting host proteins and membranes, by co-opting and modulating protein and ribonucleoprotein complexes, and by altering cellular pathways during infection. To achieve robust replication, plus-stranded RNA viruses interact with numerous cellular molecules via protein–protein, RNA–protein, and protein–lipid interactions using molecular mimicry and other means. These interactions lead to the transformation of the host cells into viral “factories" that can produce 10,000–1,000,000 progeny RNAs per infected cell. This chapter presents the progress that was made largely in the last 15 years in understanding virus–host interactions during RNA virus replication. The most commonly employed approaches to identify host factors that affect plus-stranded RNA virus replication are described. In addition, we discuss many of the identified host factors and their proposed roles in RNA virus replication. Altogether, host factors are key determinants of the host range of a given virus and affect virus pathology, host–virus interactions, as well as virus evolution. Studies on host factors also contribute insights into their normal cellular functions, thus promoting understanding of the basic biology of the host cell. The knowledge obtained in this fast-progressing area will likely stimulate the development of new antiviral methods as well as novel strategies that could make plus-stranded RNA viruses useful in bio- and nanotechnology.

An authentic 3' noncoding region is necessary for efficient poliovirus replication

Picornavirus RNA replication involves the specific synthesis of negative-strand intermediates followed by an accumulation of positive-strand viral RNA in the presence of a multitude of cellular mRNAs. Previously, in an effort to identify cis-acting elements required for initiation of negative-strand RNA synthesis, we deleted the entire 3' noncoding regions from human rhinovirus and poliovirus genomic RNAs. These deletion mutation transcripts displayed a severe delay in RNA accumulation following transfection of HeLa cells. Interestingly, in subsequent infection of HeLa cells, the deletion-mutant poliovirus displayed only a moderate deficiency in RNA synthesis. These data suggested that the delay in the production of cytopathic effects after transfection may have been due to an RNA replication defect overcome by the accumulation of a compensatory mutation(s) generated during initial rounds of RNA synthesis. In this study, we have sequenced the entire genome of the deletion-mutant virus and found only two nucleotide changes from the parental clone. Transfection analysis of these sequence variants revealed that the sequence changes did not provide compensatory functions for the 3' noncoding region deletion mutation replication defect. Further examination of the deletion mutant phenotype revealed that the severe replication defect following RNA transfection is due, in part, to nonviral terminal sequences present in the in vitro-derived deletion mutation transcripts. Our data suggest that poliovirus RNA harboring a complete 3' noncoding region deletion mutation is infectious (not merely quasi-infectious).

3'-Terminal sequence in poliovirus negative-strand templates is the primary cis-acting element required for VPgpUpU-primed positive-strand initiation

The 5' cloverleaf in poliovirus RNA has a direct role in regulating the stability, translation, and replication of viral RNA. In this study, we investigated the role of stem a in the 5' cloverleaf in regulating the stability and replication of poliovirus RNA in HeLa S10 translation-replication reactions. Our results showed that disrupting the duplex structure of stem a destabilized viral RNA and inhibited efficient negative-strand synthesis. Surprisingly, the duplex structure of stem a was not required for positive-strand synthesis. In contrast, altering the primary sequence at the 5'-terminal end of stem a had little or no effect on negative-strand synthesis but dramatically reduced positive-strand initiation and the formation of infectious virus. The inhibition of positive-strand synthesis observed in these reactions was most likely a consequence of nucleotide alterations in the conserved sequence at the 3' ends of negative-strand RNA templates. Previous studies suggested that VPgpUpU synthesized on the cre(2C) hairpin was required for positive-strand synthesis. Therefore, these results are consistent with a model in which preformed VPgpUpU serves as the primer for positive-strand initiation on the 3'AAUUUUGUC5' sequence at the 3' ends of negative-strand templates. Our results suggest that this sequence is the primary cis-acting element that is required for efficient VPgpUpU-primed positive-strand initiation.

Functional interaction of heterogeneous nuclear ribonucleoprotein C with poliovirus RNA synthesis initiation complexes

We had previously demonstrated that a cellular protein specifically interacts with the 3' end of poliovirus negative-strand RNA. We now report the identity of this protein as heterogeneous nuclear ribonucleoprotein (hnRNP) C1/C2. Formation of an RNP complex with poliovirus RNA was severely impaired by substitution of a lysine, highly conserved among vertebrates, with glutamine in the RNA recognition motif (RRM) of recombinant hnRNP C1, suggesting that the binding is mediated by the RRM in the protein. We have also shown that in a glutathione S-transferase (GST) pull-down assay, GST/hnRNP C1 binds to poliovirus polypeptide 3CD, a precursor to the viral RNA-dependent RNA polymerase, 3D(pol), as well as to P2 and P3, precursors to the nonstructural proteins. Truncation of the auxiliary domain in hnRNP C1 (C1DeltaC) diminished these protein-protein interactions. When GST/hnRNP C1DeltaC was added to in vitro replication reactions, a significant reduction in RNA synthesis was observed in contrast to reactions supplemented with wild-type fusion protein. Indirect functional depletion of hnRNP C from in vitro replication reactions, using poliovirus negative-strand cloverleaf RNA, led to a decrease in RNA synthesis. The addition of GST/hnRNP C1 to the reactions rescued RNA synthesis to near mock-depleted levels. Furthermore, we demonstrated that poliovirus positive-strand and negative-strand RNA present in cytoplasmic extracts prepared from infected HeLa cells coimmunoprecipitated with hnRNP C1/C2. Our findings suggest that hnRNP C1 has a role in positive-strand RNA synthesis in poliovirus-infected cells, possibly at the level of initiation.

Regulation of poliovirus 3C protease by the 2C polypeptide

Poliovirus-encoded nonstructural polypeptide 2C is a multifunctional protein that plays an important role in viral RNA replication. 2C interacts with both intracellular membranes and virus-specific RNAs and has ATPase and GTPase activities. Extensive computer analysis of the 2C sequence revealed that in addition to the known ATPase-, GTPase-, membrane-, and RNA-binding domains it also contains several "serpin" (serine protease inhibitor) motifs. We provide experimental evidence suggesting that 2C is indeed capable of regulating virus-encoded proteases. The purified 2C protein inhibits 3C(pro)-catalyzed cleavage of cellular transcription factors at Q-G sites in vitro. It also inhibits cleavage of a viral precursor by the other viral protease, 2A(pro). However, at least three cellular proteases appear not to be inhibited by 2C in vitro. The 2C-associated protease inhibitory activity can be depleted by anti-2C antibody. A physical interaction between 2C and His-tagged 3C(pro) can be demonstrated in vitro by coimmunoprecipitation of 2C with anti-His antibody. Deletion analysis suggests that the 2C central and C-terminal domains that include several serpin motifs are important for 3C(pro)-inhibitory activity. To examine the 2C protease inhibitory activity in vivo, stable HeLa cell lines were made that express 2C in an inducible fashion. Infection of 2C-expressing cells with poliovirus led to incomplete (or inefficient) processing of viral precursor polypeptides compared to control cell lines containing the vector alone. These results suggest that 2C can negatively regulate the viral protease 3C(pro). The possible role of the 2C protease inhibitory activity in viral RNA replication is discussed.

Regulation of picornavirus gene expression

Members of the Picornaviridae are positive- strand RNA viruses that cause a variety of human diseases such as poliomyelitis, the common cold, myocarditis, and hepatitis. Although the diseases caused by picornaviruses are diverse, the genome organization and mechanisms of gene expression are highly conserved among family members. This review will discuss the mechanisms of viral gene expression including cap-independent translation initiation, host cell translation shut off, viral polyprotein processing, and RNA replication.

Foot-and-mouth disease

Foot-and-mouth disease (FMD) is a highly contagious disease of cloven-hoofed animals. The disease was initially described in the 16th century and was the first animal pathogen identified as a virus. Recent FMD outbreaks in developed countries and their significant economic impact have increased the concern of governments worldwide. This review describes the reemergence of FMD in developed countries that had been disease free for many years and the effect that this has had on disease control strategies. The etiologic agent, FMD virus (FMDV), a member of the Picornaviridae family, is examined in detail at the genetic, structural, and biochemical levels and in terms of its antigenic diversity. The virus replication cycle, including virus-receptor interactions as well as unique aspects of virus translation and shutoff of host macromolecular synthesis, is discussed. This information has been the basis for the development of improved protocols to rapidly identify disease outbreaks, to differentiate vaccinated from infected animals, and to begin to identify and test novel vaccine candidates. Furthermore, this knowledge, coupled with the ability to manipulate FMDV genomes at the molecular level, has provided the framework for examination of disease pathogenesis and the development of a more complete understanding of the virus and host factors involved.

Cellular proteins from human monocytes bind to dengue 4 virus minus-strand 3' untranslated region RNA

The synthesis of plus and minus RNA strands of several RNA viruses requires as a first step the interaction of some viral regulatory sequences with cellular and viral proteins. The dengue 4 virus genome, a single-stranded, positive-polarity RNA, is flanked by two untranslated regions (UTR) located in the 5' and 3' ends. The 3'UTR in the minus-strand RNA [3'UTR (-)] has been thought to function as a promoter for the synthesis of plus-strand RNA. To study the initial interaction between this 3'UTR and cellular and viral proteins, mobility shift assays were performed, and four ribonucleoprotein complexes (I through IV) were formed when uninfected and infected U937 cells (human monocyte cell line) interacted with the 3'UTR (-) of dengue 4 virus. Cross-linking assays with RNAs containing the complete 3'UTR (-) (nucleotides [nt] 101 to 1) or a partial sequence from nt 101 to 45 and nt 44 to 1 resulted in specific binding of some cellular proteins. Supermobility shift and immunoprecipitation assays demonstrated that the La protein forms part of these complexes. To determine the region in the 3' UTR that interacted with the La protein, two deletion mutants were generated. The mutant (del-96), with a deletion of nt 96 to 101, was unable to interact with the La protein, suggesting that La interacted with the 5' portion of the 3'UTR (-). Complex I, which was the main ribonucleoprotein complex formed with the 3'UTR (-) and which had the fastest electrophoretic migration, contained proteins such as calreticulin and protein disulfide isomerase, which constitute important components of the endoplasmic reticulum.

Poliovirus internal ribosome entry segment structure alterations that specifically affect function in neuronal cells: molecular genetic analysis

Translation of poliovirus RNA is driven by an internal ribosome entry segment (IRES) present in the 5' noncoding region of the genomic RNA. This IRES is structured into several domains, including domain V, which contains a large lateral bulge-loop whose predicted secondary structure is unclear. The primary sequence of this bulge-loop is strongly conserved within enteroviruses and rhinoviruses: it encompasses two GNAA motifs which could participate in intrabulge base pairing or (in one case) could be presented as a GNRA tetraloop. We have begun to address the question of the significance of the sequence conservation observed among enterovirus reference strains and field isolates by using a comprehensive site-directed mutagenesis program targeted to these two GNAA motifs. Mutants were analyzed functionally in terms of (i) viability and growth kinetics in both HeLa and neuronal cell lines, (ii) structural analyses by biochemical probing of the RNA, and (iii) translation initiation efficiencies in vitro in rabbit reticulocyte lysates supplemented with HeLa or neuronal cell extracts. Phenotypic analyses showed that only viruses with both GNAA motifs destroyed were significantly affected in their growth capacities, which correlated with in vitro translation defects. The phenotypic defects were strongly exacerbated in neuronal cells, where a temperature-sensitive phenotype could be revealed at between 37 and 39.5 degrees C. Biochemical probing of mutated domain V, compared to the wild type, demonstrated that such mutations lead to significant structural perturbations. Interestingly, revertant viruses possessed compensatory mutations which were distant from the primary mutations in terms of sequence and secondary structure, suggesting that intradomain tertiary interactions could exist within domain V of the IRES.

Cellular protein binds to sequences near the 5' terminus of potato virus X RNA that are important for virus replication

The sequences in the 5'-nontranslated region (NTR) of Potato virus X (PVX) genomic RNA were previously reported to contain several regulatory elements that are required for genomic and subgenomic RNA accumulation. To investigate whether cellular proteins bind to these elements, we conducted electrophoretic mobility shift assays (EMSA) with protoplast protein extracts and RNA sequences from the PVX 5'-NTR. These analyses showed that the 5' region of PVX positive-strand RNA formed complexes with cellular proteins. UV cross-linking studies of complexes formed with various deletions of the PVX RNA indicated that a 54-kDa cellular protein (p54) was bound to nt 1-46 at the 5' terminus of PVX RNA. Site-directed mutations introduced within this 46-nt region further indicated that an ACCA sequence element located at nt 10-13 was important for optimal binding. In addition, mutations that decreased the affinity of the template RNA for the cellular factor decreased PVX plus-strand RNA accumulation in protoplasts. These studies suggest that the p54 may function in PVX RNA replication by binding to the 5' terminus of the viral genomic RNA.

Interaction of poliovirus-encoded 2C/2BC polypeptides with the 3' terminus negative-strand cloverleaf requires an intact stem-loop b

The poliovirus-encoded, membrane-associated polypeptide 2C and its precursor, 2BC, is believed to be required for initiation and elongation of viral RNA synthesis. Previous studies have shown that the 2C polypeptide specifically interacts with the 3'-terminal sequence of poliovirus negative-strand RNA. This interaction is facilitated by the presence of the conserved sequence UGUUUU in the "stem a" within the 3'-terminal cloverleaf structure. We show that the 2C precursor, 2BC, also interacts with the 3'-terminal cloverleaf of the negative-strand RNA. We also demonstrate here that interaction of 2C/2BC with the negative strand 3'-terminal sequence not only depends on an intact "stem a" containing the UGUUUU sequence but is equally influenced by the presence of an intact "stem b" within the negative-strand cloverleaf. The results presented here suggest that the spatial configuration of stem a UGUUUU sequence with respect to an intact stem-b is crucial for 2C/2BC interaction with the 3'-terminal negative-strand cloverleaf structure.

Interaction of cellular proteins with the 5' end of Norwalk virus genomic RNA

The lack of a susceptible cell line and an animal model for Norwalk virus (NV) infection has prompted the development of alternative strategies to generate in vitro RNAs that approximate the authentic viral genome. This approach has allowed the study of viral RNA replication and gene expression. In this study, using mobility shift and cross-linking assays, we detected several cellular proteins from HeLa and CaCo-2 cell extracts that bind to, and form stable complexes with, the first 110 nucleotides of the 5' end of NV genomic RNA, a region previously predicted to form a double stem-loop structure. These proteins had molecular weights similar to those of the HeLa cellular proteins that bind to the internal ribosomal entry site of poliovirus RNA. HeLa proteins La, PCBP-2, and PTB, which are important for poliovirus translation, and hnRNP L, which is possibly implicated in hepatitis C virus translation, interact with NV RNA. These protein-RNA interactions are likely to play a role in NV translation and/or replication.

Functional features of the bovine enterovirus 5'-non-translated region

The bovine enterovirus (BEV) serotypes exhibit unique features of the non-translated regions (NTRs) which separate them from the other enteroviruses. Their most remarkable property is an additional genome region of 110 nt located between the 5'-cloverleaf and the internal ribosome entry site (IRES). This genome region has the potential to form an additional cloverleaf structure (domain I*) separated from the 5'-cloverleaf (domain I) by a small stem-loop (domain I**). Other characteristics involve the putative IRES domains III and VI. In order to investigate the features of the 5'-NTR, several full-length coxsackievirus B3 (CVB3) cDNA plasmids with hybrid 5'-NTRs were engineered. After exchange of the CVB3 cloverleaf with the BEV1 genome region representing both cloverleafs, a viable virus chimera was generated. Deletion of domain I** within the exchanged region also yielded viable virus albeit with reduced growth capacity. Deletion of sequences encoding either the first or the second BEV cloverleaf resulted in non-infectious constructs. Hybrid plasmids with exchanges of the IRES-encoding sequence or the complete 5'-NTR were non-infectious. Transfection experiments with SP6 transcripts containing 5'-NTRs fused to the luciferase message indicated that IRES-driven translation is enhanced by the presence of the CVB3 cloverleaf and both BEV1 cloverleaf structures, respectively. Deletion of either the first or the second BEV cloverleaf domain reduced but did not abolish enhanced luciferase expression. These results suggest that the substitution of two putative BEV cloverleaf structures for the putative coxsackieviral cloverleaf yields viable virus, while BEV sequences encoding the IRES fail to functionally replace CVB3 IRES-encoding sequences.

Paradoxes of the replication of picornaviral genomes

A wealth of experimental data on the mechanism of the picornavirus genome replication has accumulated. Not infrequently, however, conclusions derived from these data appear to contradict each other. On the one hand, initiation of a complementary RNA strand can be demonstrated to occur in a solution containing only the poliovirus RNA polymerase, VPg, uridine triphosphate, poly(A) template and appropriate ions. On the other hand, convincing experiments suggest that efficient initiation of a viral complementary RNA strand requires complex cis-acting signals on the viral RNA template, additional viral and possibly cellular proteins as well as a membrane-containing environment. On the one hand, there is evidence that the viral RNA, in order to be replicated, should first be translated, but on the other hand, the viral RNA polymerase appears to be unable to overcome the ribosome barrier. Possible solutions for these and several other similar paradoxes are discussed, along with less contradictory results on the properties of the picornaviral replicative proteins. Recent results suggesting that recombination and other rearrangements of the viral RNA genomes may be accomplished not only by the replicative template switching but also by nonreplicative mechanisms are also briefly reviewed.

Intracellular determinants of picornavirus replication

Viruses replicate in a restricted number of hosts and tissues. In addition to viral receptors, several intracellular factors can be involved in determining tissue tropism. Many proteins have recently been implicated in picornavirus translation and RNA replication. Although the functional role of these proteins has not been established in vivo, it is possible that they determine cell-type tropism and the pathogenic outcome of the infection.

Rescue of defective poliovirus RNA replication by 3AB-containing precursor polyproteins

This study demonstrates the in vitro complementation of an RNA replication-defective lesion in poliovirus RNA by providing a replicase/polymerase precursor polypeptide [P3(wt) (wild type)] in trans. The replication-defective mutation was a phenylalanine-to-histidine change (F69H) in the hydrophobic domain of the membrane-associated viral protein 3AB. RNAs encoding wild-type forms of protein 3AB or the P3 precursor polypeptide were cotranslated with full-length poliovirus RNAs containing the F69H mutation in a HeLa cell-free translation/replication assay in an attempt to trans complement the RNA replication defect exhibited by the 3AB(F69H) lesion. Unexpectedly, generation of 3AB(wt) in trans was not able to efficiently complement the defective replication complex; however, cotranslation of the large P3(wt) precursor protein allowed rescue of RNA replication. Furthermore, P3 proteins harboring mutations that resulted in either an inactive polymerase or an inactive proteinase domain displayed differential abilities to trans complement the RNA replication defect. Our results indicate that replication proteins like 3AB may need to be delivered to the poliovirus replication complex in the form of a larger 3AB-containing protein precursor prior to complex assembly rather than as the mature viral cleavage product.

Translation initiation of a cardiac voltage-gated potassium channel by internal ribosome entry

The mammalian Kv1.4 voltage-gated potassium channel mRNA contains an unusually long (1.2 kilobases) 5'-untranslated region (UTR) and includes 18 AUG codons upstream of the authentic site of translation initiation. Computer-predicted secondary structures of this region reveal complex stem-loop structures that would serve as barriers to 5' --> 3' ribosomal scanning. These features suggested that translation initiation in Kv1.4 might occur by the mechanism of internal ribosome entry, a mode of initiation employed by a variety of RNA viruses but only a limited number of vertebrate genes. To test this possibility we introduced the 5'-UTR of mouse Kv1.4 mRNA into the intercistronic region of a bicistronic vector containing two tandem reporter genes, chloramphenicol acetyltransferase and luciferase. The control construct translated only the upstream chloramphenicol cistron in transiently transfected mammalian cells. In contrast, the construct containing the mKv1.4 UTR efficiently translated the luciferase cistron as well, demonstrating the presence of an internal ribosome entry segment. Progressive 5' --> 3' deletions localized the activity to a 3'-proximal 200-nucleotide fragment. Suppression of cap-dependent translation by extracts from poliovirus-infected HeLa cells in an in vitro translation assay eliminated translation of the upstream cistron while allowing translation of the downstream cistron. Our results indicate that the 5'-untranslated region of mKv1.4 contains a functional internal ribosome entry segment that may contribute to unusual and physiologically important modes of translation regulation for this and other potassium channel genes.

Viral ribonucleoprotein complex formation and nucleolar-cytoplasmic relocalization of nucleolin in poliovirus-infected cells

The poliovirus 3' noncoding region (3'NCR) is involved in the efficient synthesis of viral negative-stranded RNA molecules. A strong interaction between a 105-kDa host protein and the wild-type 3'NCR, but not with a replication-defective mutant 3'NCR, was detected. This 105-kDa protein was identified as nucleolin which predominantly resides in the nucleolus and has been proposed to function in the folding of rRNA precursor molecules. A functional role for nucleolin in viral genome amplification was examined in a cell-free extract which has been shown to support the assembly of infectious virus from virion RNA. At early times of viral gene expression, extracts depleted of nucleolin produced less infectious virus than extracts depleted of fibrillarin, another resident of the nucleolus, indicating a functional role of nucleolin in the early stages of the viral life cycle in this in vitro system. Immunofluorescence analysis of uninfected and infected cells showed a nucleocytoplasmic relocalization of nucleolin, but not of fibrillarin, in poliovirus-infected cells. Relocalization of nucleolin was not simply a consequence of virally induced inhibition of translation or transcription, because inhibitors of translation or transcription did not induce nucleolar-cytoplasmic relocalization of nucleolin. These findings suggest a novel virus-induced mechanism by which certain nucleolar proteins are selectively redistributed in infected cells.

Direct cleavage of elF4G by poliovirus 2A protease is inefficient in vitro

Previously, the purified recombinant 2A proteases (2Apro) of coxsackievirus B4 (CVB4) and human rhinovirus type 2 (HRV2) were shown to cleave synthetic peptides derived from human or rabbit elF4G as well as elF4G protein purified from rabbit reticulocytes. These results were in contrast to previous evidence which supported the view that elF4G cleavage activity in poliovirus-infected HeLa cells required a cellular factor(s) activated by poliovirus (PV) 2Apro. In the present study, recombinant PV 2Apro was shown to cleave either rabbit or human elF4G or their derived peptides in direct cleavage reactions, but cleaved the 4G-derived peptides with 100-fold lower efficiency than with a peptide derived from the poliovirus polyprotein. In these experiments, up to 25-fold molar excess of 2Apro over elF4G protein was required to cause greater than 50% cleavage. CVB4 2Apro was also tested in peptide cleavage assays under the same conditions as PV 2Apro and was found to cleave all elF4G substrates with efficiencies similar to PV 2Apro. Finally, cleavage reactions utilizing recombinant elF4G containing a G486E substitution at the cleavage site for CVB4 and HRV2 proteases resulted in drastically reduced cleavage by PV 2Apro, similar to the reduction previously seen with HRV2 and CVB4 2Apro, confirming that all three viral 2A proteases recognize the same cleavage site on elF4G. These data show that PV 2Apro can directly cleave elF4G in vitro with efficiencies similar to those of CVB 2Apro, but cleavage efficiency of elF4G is approximately 1000-fold lower than cleavage of a peptide derived from the authentic 2A cleavage site on the poliovirus polyprotein.

Effects of poliovirus 3AB protein on 3D polymerase-catalyzed reaction

Poliovirus RNA replication requires the activities of a viral RNA-dependent RNA polymerase, 3Dpol, in conjunction with several additional viral and likely cellular proteins. The importance of both the 3A and 3B coding regions has been documented previously by genetic tests, and their biochemical activities have been the subject of several recent investigations. In this study, we examined the previously reported stimulation of 3D-catalyzed RNA synthesis by 3AB. We show that 3AB does not stimulate RNA synthesis on templates that are stably base paired to a primer, indicating that 3AB does not stabilize or otherwise activate 3Dpol for chain elongation. Similarly, it does not alter the kinetic parameters or binding affinities of 3D for substrates. In the absence of a primer, or in the presence of a primer that does not form a stable hybrid with the template, 3AB increases the utilization of 3'-hydroxyl termini as sites for chain elongation by 3D, and thereby stimulates RNA synthesis. 3AB may interact with and stabilize these sites and/or may recruit 3Dpol to the site, resulting in stimulation of the initiation of elongation events. We propose that this activity is required for stabilizing weak interactions that occur during nucleotidyl-protein-primed initiation events in the viral RNA replication complex.

Cellular factors in the transcription and replication of viral RNA genomes: a parallel to DNA-dependent RNA transcription

Viral RNA replication and transcription involves not only viral RNA-dependent RNA polymerases, but also cellular proteins, the majority of which are subverted from the RNA-processing or translation machineries of host cells. These factors interact with viral RNA or polymerases to form transcription or replication ribonucleoprotein complexes and may provide template specificity for RNA-dependent RNA synthesis, suggesting a close parallel to the mechanism of DNA-dependent RNA synthesis. The types of cellular proteins involved and their modes of action are reviewed.

Poliovirus-encoded 2C polypeptide specifically binds to the 3'-terminal sequences of viral negative-strand RNA

The poliovirus-encoded, membrane-associated polypeptide 2C is believed to be required for initiation and elongation of RNA synthesis. We have expressed and purified recombinant, histidine-tagged 2C and examined its ability to bind to the first 100 nucleotides of the poliovirus 5' untranslated region of the positive strand and its complementary 3'-terminal negative-strand RNA sequences. Results presented here demonstrate that the 2C polypeptide specifically binds to the 3'-terminal sequences of poliovirus negative-strand RNA. Since this region is believed to form a stable cloverleaf structure, a number of mutations were constructed to examine which nucleotides and/or structures within the cloverleaf are essential for 2C binding. Binding of 2C to the 3'-terminal cloverleaf of the negative-strand RNA is greatly affected when the conserved sequence, UGUUUU, in stem a of the cloverleaf is altered. Mutational studies suggest that interaction of 2C with the 3'-terminal cloverleaf of negative-strand RNA is facilitated when the sequence UGUUUU is present in the context of a double-stranded structure. The implication of 2C binding to negative-strand RNA in viral replication is discussed.

Replication-competent picornaviruses with complete genomic RNA 3' noncoding region deletions

The genomic RNA 3' noncoding region is believed to be a major cis-acting molecular genetic determinant for regulating picornavirus negative-strand RNA synthesis by promoting replication complex recognition. We report the replication of two picornavirus RNAs harboring complete deletions of the genomic RNA 3' noncoding regions. Our results suggest that while specific 3'-terminal RNA sequences and/or secondary structures may have evolved to promote or regulate negative-strand RNA synthesis, the basic mechanism of replication initiation is not strictly template specific and may rely primarily upon the proximity of newly translated viral replication proteins to the 3' terminus of template RNAs within tight membranous replication complexes.

Application of genome sequence information to the classification of bovine enteroviruses: the importance of 5'- and 3'-nontranslated regions

Comparative genomics of viruses in evolutionary and phylogenetic studies is well established. Previous nucleic acid sequence analyses have demonstrated that enteroviruses and rhinoviruses of the family Picornaviridae exhibit a similar structure of the 5'-nontranslated region (NTR) differing significantly from the 5'-NTR of cardiovirus, aphthovirus, hepatovirus, and echovirus 22 (provisionally parechovirus 1). Available nucleotide sequence information of the 5'- and 3'-nontranslated regions of more than 70 serotypes of enteroviruses, bovine enteroviruses and rhinoviruses has been compared and correlated with previous findings obtained after analysis of the coding and noncoding genome regions. As a result, the 5'- and 3'-NTRs of all three virus groups are characterized by group-specific nucleotide sequences. Focusing on bovine enterovirus (BEV) serotypes, unique characteristics in all secondary structures of the NTRs were observed. These features clearly separate the BEVs from the human enteroviruses and rhinoviruses. Concerning the 5'-NTR, the most remarkable property is an insertion of about 110 nucleotides between the putative cloverleaf structure at the very 5'-end of the viral genome and the IRES element. This insertion was demonstrated for BEV 1 and 2 and has a predicted folding pattern which is very similar to the 5'-cloverleaf structure. One stem-loop of this second cloverleaf is almost identical to the 3CDpro-binding domain of rhinoviral 5'-cloverleafs. It was also demonstrated that the IRES elements and the 3'-NTRs of both, enteroviruses and rhinoviruses, have group-specific features which differ significantly from the corresponding genome regions of BEV. These results suggest that bovine enteroviruses hold an exceptional taxonomic position besides the established genera Enterovirus and Rhinovirus. Within the Enterovirus and Rhinovirus genera, the existence of virus clusters representing subgenera was previously proposed. Whereas the 5'-NTRs of the four human enterovirus clusters fall into two groups, all four clusters have characteristic secondary structures at the 3'-NTR supporting the concept of enterovirus clusters. For rhinoviruses, the existence of two virus clusters was confirmed.

Processing of a cellular polypeptide by 3CD proteinase is required for poliovirus ribonucleoprotein complex formation

Poliovirus interactions with host cells were investigated by studying the formation of ribonucleoprotein complexes at the 3' end of poliovirus negative-strand RNA which are presumed to be involved in viral RNA synthesis. It was previously shown that two host cell proteins with molecular masses of 36 and 38 kDa bind to the 3' end of viral negative-strand RNA at approximately 3 to 4 h after infection. We tested the hypothesis that preexisting cellular proteins are modified during the course of infection and are subsequently recruited to play a role in viral replication. It was demonstrated that the 38-kDa protein, either directly or indirectly, is the product of processing by poliovirus 3CD/3C proteinase. Only the modified 38-kDa protein, not its precursor protein, has a high affinity for binding to the 3' end of viral negative-strand RNA. This modification depends on proteolytically active proteinase, and a direct correlation between the levels of 3CD proteinase and the 38-kDa protein was demonstrated in infected tissue culture cells. The nucleotide (nt) 5-10 region (positive-strand numbers) of poliovirus negative-strand RNA is important for binding of the 38-kDa protein. Deletion of the nt 5-10 region in full-length, positive-strand RNA renders the RNA noninfectious in transfection experiments. These results suggest that poliovirus 3CD/3C proteinase processes a cellular protein which then plays an essential role during the viral life cycle.

Reversible dissociation of the poliovirus replication complex: functions and interactions of its components in viral RNA synthesis

Membrane-bound replication complexes containing transcriptionally active replicative intermediates (RI) can be isolated from poliovirus-infected HEp-2 cells and consist of rosette-like structures of virus-induced vesicles surrounding the replicating viral RNA. At low ionic strength and low temperature, the rosettes reversibly dissociate into individual tubulated vesicles. As determined by immunoelectron microscopy and immunoprecipitation, the vesicles carry a set of viral structural and nonstructural proteins as well as RI RNA. At 30 degrees C, the vesicles reassociate into rosettes synthesizing plus-strand RNA in the RI. The in vitro transcriptional activities of rosettes and vesicles kept separated by high dilution were assessed by an RNase protection assay. The synthesis of the first 178 nucleotides at the 5' end of the plus strand was considered to reflect initiation, and the detection of a 530-nucleotide fragment in the P2 genomic region was considered to reflect elongation. It could be shown that the initiation and elongation of plus strands on individual vesicles are comparable to those in rosettes, with initiation proceeding in de novo-assembled initiation complexes. By use of detergent treatment it was found that initiation, but not elongation, is dependent on vesicular membranes.

An eight-nucleotide sequence in the potato virus X 3' untranslated region is required for both host protein binding and viral multiplication

Gel retardation and UV-cross-linking techniques were used to demonstrate that two tobacco proteins, with approximate molecular masses of 28 and 32 kDa, bind to a site within the 3' region of potato virus X (PVX) genomic RNA. The protein binding is specific, in that a 50-fold excess of unlabeled probe prevents formation of the complexes but no reduction is observed with a 2,000-fold molar excess of yeast tRNA. Complex formation is inhibited by poly(U) but is relatively unaffected by poly(A), poly(G), or poly(C-I). PVX RNA-host protein complex formation occurs in vitro at salt concentrations up to 400 mM. Deletion mapping indicates that the proteins bind within the 3' untranslated region (UTR) of PVX genomic RNA and that an 8-nucleotide U-rich sequence (5'-UAUUUUCU) is required for the binding. Deletion of the 8-nucleotide U-rich region from the 3' UTR of a sensitive PVX reporter virus that carries the luciferase gene in place of the PVX coat protein gene results in a more than 70,000-fold reduction in luciferase expression in tobacco protoplasts. RNA probes carrying the sequence GCGC in place of the central four contiguous uridines of the 8-nucleotide U-rich motif fail to bind host protein at detectable levels, and the same mutation, when introduced into the PVX reporter virus, eliminates viral multiplication. Mutations of 1 or 2 nucleotides within the same four uridines reduced both binding of host proteins and replication of reporter virus. These results indicate that the 8-nucleotide U-rich motif within the PVX 3' UTR is important for some aspect of viral multiplication and suggest that host protein binding plays a role in the process.

Human protein Sam68 relocalization and interaction with poliovirus RNA polymerase in infected cells

A HeLa cDNA expression library was screened for human polypeptides that interacted with the poliovirus RNA-dependent RNA polymerase, 3D, using the two-hybrid system in the yeast Saccharomyces cerevisiae. Sam68 (Src-associated in mitosis, 68 kDa) emerged as the human cDNA that, when fused to a transcriptional activation domain, gave the strongest 3D interaction signal with a LexA-3D hybrid protein. 3D polymerase and Sam68 coimmunoprecipitated from infected human cell lysates with antibodies that recognized either protein. Upon poliovirus infection, Sam68 relocalized from the nucleus to the cytoplasm, where poliovirus replication occurs. Sam68 was isolated from infected cell lysates with an antibody that recognizes poliovirus protein 2C, suggesting that it is found on poliovirus-induced membranes upon which viral RNA synthesis occurs. These data, in combination with the known RNA- and protein-binding properties of Sam68, make Sam68 a strong candidate for a host protein with a functional role in poliovirus replication.

Attenuation stem-loop lesions in the 5' noncoding region of poliovirus RNA: neuronal cell-specific translation defects

The nucleotide at position 480 in the 5' noncoding region of the viral RNA genome plays an important role in directing the attenuation phenotype of the Sabin vaccine strain of poliovirus type 1. In vitro translation studies have shown that the attenuated viral genomes of the Sabin strains direct levels of viral protein synthesis lower than those of their neurovirulent counterparts. We previously described the isolation of pseudorevertant polioviruses derived from transfections of HeLa cells with genome-length RNA harboring an eight-nucleotide lesion in a stem-loop structure (stem-loop V) that contains the attenuation determinant at position 480 (A. A. Haller and B. L. Semler, J. Virol. 66:5075-5086, 1992). This stem-loop structure is a major component of the poliovirus internal ribosome entry site required for initiation of viral protein synthesis. The eight-nucleotide lesion (X472) was lethal for virus growth and gave rise only to viruses which had partially reverted nucleotides within the original substituted sequences. In this study, we analyzed two of the poliovirus revertants (X472RI and X472R2) for cell-type-specific growth properties. The X472RI and X472R2 RNA templates directed protein synthesis to wild-type levels in in vitro translation reaction mixtures supplemented with crude cytoplasmic HeLa cell extracts. In contrast, the same X472 revertant RNAs displayed a decreased translation initiation efficiency when translated in a cell-free system supplemented with extracts from neuronal cells. This translation initiation defect of the X472R templates correlated with reduced yields of infectious virus particles in neuronal cells compared with those obtained from HeLa cells infected with the X472 poliovirus revertants. Our results underscore the important of RNA secondary structures within the poliovirus internal ribosome entry site in directing translation initiation and suggest that such structures interact with neuronal cell factors in a specific manner.

Functional oligomerization of poliovirus RNA-dependent RNA polymerase

Using a hairpin primer/template RNA derived from sequences present at the 3' end of the poliovirus genome, we investigated the RNA-binding and elongation activities of highly purified poliovirus 3D polymerase. We found that surprisingly high polymerase concentrations were required for efficient template utilization. Binding of template RNAs appeared to be the primary determinant of efficient utilization because binding and elongation activities correlated closely. Using a three-filter binding assay, polymerase binding to RNA was found to be highly cooperative with respect to polymerase concentration. At pH 5.5, where binding was most cooperative, a Hill coefficient of 5 was obtained, indicating that several polymerase molecules interact to retain the 110-nt RNA in a filter-bound complex. Chemical crosslinking with glutaraldehyde demonstrated physical polymerase-polymerase interactions, supporting the cooperative binding data. We propose a model in which poliovirus 3D polymerase functions both as a catalytic polymerase and as a cooperative single-stranded RNA-binding protein during RNA-dependent RNA synthesis.

RNA-protein interactions directed by the 3' end of human rhinovirus genomic RNA

The replication of a picornavirus genomic RNA is a template-specific process involving the recognition of viral RNAs as target replication templates for the membrane-bound viral replication initiation complex. The virus-encoded RNA-dependent RNA polymerase, 3Dpol, is a major component of the replication complex; however, when supplied with a primed template, 3Dpol is capable of copying polyadenylated RNAs which are not of viral origin. Therefore, there must be some other molecular mechanism to direct the specific assembly of the replication initiation complex at the 3' end of viral genomic RNAs, presumably involving cis-acting binding determinants within the 3' noncoding region (3' NCR). This report describes the use of an in vitro UV cross-linking assay to identify proteins which interact with the 3' NCR of human rhinovirus 14 RNA. A cellular protein(s) was identified in cytoplasmic extracts from human rhinovirus 14-infected cells which had a marked binding preference for RNAs containing the rhinovirus 3' NCR sequence. This protein(s) showed reduced cross-linking efficiency for a 3' NCR with an engineered deletion. Virus recovered from RNA transfections with in vitro transcribed RNA containing the same 3' NCR deletion demonstrated a defective replication phenotype in vivo. Cross-linking experiments with RNAs containing the poliovirus 3' NCR and cytoplasmic extracts from poliovirus-infected cells produced an RNA-protein complex with indistinguishable electrophoretic properties, suggesting that the appearance of the cellular protein(s) may be a common phenomenon of picornavirus infection. We suggest that the observed cellular protein(s) is sequestered or modified as a result of rhinovirus or poliovirus infection and is utilized in viral RNA replication, perhaps by binding to the 3' NCR as a prerequisite for replication complex assembly at the 3' end of the viral genomic RNA.