Evolution of Sindbis virus with a low-methionine-resistant phenotype is dependent both on a pre-existing mutation and on the methionine concentration in the medium.

SVlm21 is a mutant of Sindbis virus which was isolated by serial passage of virus in mosquito cells maintained in low-methionine medium; it therefore has a low-methionine-resistant (LMR) phenotype. This phenotype requires mutations at nts 319 and 321; these mutations result in Arg to Leu and Ser to Cys changes at positions 87 and 88 respectively in the viral methyl transferase, nsP1. To better understand the genesis of SVlm21, we carried out serial passages of viruses having only one of these amino acid changes, but in mosquito cells maintained in normal methionine-medium. Whether the passage was begun with SV319 or with SV321, the dominant virus population which emerged always acquired the second SVlm21 amino acid change. However, when the passage was begun with virus having neither the nt 319 or the nt321 mutation, even after many passages neither of these mutations was seen in the passaged virus population. Virus with the LMR phenotype emerged earlier when the virus encoded a wild-type RDRP (passage 4) rather than the mutant RDRP encoded by SVpzf (passage 7). When the methionine concentration in the medium of mosquito cells was increased to 250 µM, more than 20 passages were required until the LMR phenotype predominated. Competition experiments were carried out to compare the relative fitness of SVlm21, SVwt, SV319 and SV321 to each other. Our results indicated that SVlm21 was dominant to SVwt, as well as to both SV319 and SV321. However, SV319 and SV321 were able to co-exist with SVwt implying that in these mixed infection the presence of SVwt inhibited the emergence of SVlm21. Finally, our experiments highlight how a virus population by mutation and selection can adapt to the intracellular concentration of a simple metabolite, S-adenosylmethionine.

Host factors in enterovirus 71 replication.

Enterovirus 71 (EV71) infections continue to remain an important public health problem around the world, especially in the Asia-Pacific region. There is a significant mortality rate following such infections, and there is neither any proven therapy nor a vaccine for EV71. This has spurred much fundamental research into the replication of the virus. In this review, we discuss recent work identifying host cell factors which regulate the synthesis of EV71 RNA and proteins. Three of these proteins, heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1), far-upstream element-binding protein 2 (FBP2), and FBP1 are nuclear proteins which in EV71-infected cells are relocalized to the cytoplasm, and they influence EV71 internal ribosome entry site (IRES) activity. hnRNP A1 stimulates IRES activity but can be replaced by hnRNP A2. FBP2 is a negative regulatory factor with respect to EV71 IRES activity, whereas FBP1 has the opposite effect. Two other proteins, hnRNP K and reticulon 3, are required for the efficient synthesis of viral RNA. The cleavage stimulation factor 64K subunit (CstF-64) is a host protein that is involved in the 3' polyadenylation of cellular pre-mRNAs, and recent work suggests that in EV71-infected cells, it may be cleaved by the EV71 3C protease. Such a cleavage would impair the processing of pre-mRNA to mature mRNAs. Host cell proteins play an important role in the replication of EV71, but much work remains to be done in order to understand how they act.

Subgenomic messenger RNAs: mastering regulation of (+)-strand RNA virus life cycle.

Many (+)-strand RNA viruses use subgenomic (SG) RNAs as messengers for protein expression, or to regulate their viral life cycle. Three different mechanisms have been described for the synthesis of SG RNAs. The first mechanism involves internal initiation on a (-)-strand RNA template and requires an internal SGP promoter. The second mechanism makes a prematurely terminated (-)-strand RNA which is used as template to make the SG RNA. The third mechanism uses discontinuous RNA synthesis while making the (-)-strand RNA templates. Most SG RNAs are translated into structural proteins or proteins related to pathogenesis: however other SG RNAs regulate the transition between translation and replication, function as riboregulators of replication or translation, or support RNA-RNA recombination. In this review we discuss these functions of SG RNAs and how they influence viral replication, translation and recombination.

hnRNP A1 interacts with the genomic and subgenomic RNA promoters of Sindbis virus and is required for the synthesis of G and SG RNA.

BACKGROUND: Sindbis virus (SV) is the prototype of alphaviruses which are a group of widely distributed human and animal pathogens. Heterogeneous nuclear ribonucleoprotein (hnRNP) A1 is an RNA-binding protein that shuttles between the nucleus and the cytoplasm. Our recent studies found that hnRNP A1 relocates from nucleus to cytoplasm in Sindbis virus (SV)-infected cells. hnRNP A1 binds to the 5' UTR of SV RNA and facilitates the viral RNA replication and translation. METHODS: Making use of standard molecular techniques, virology methods and an in vitro system developed by our lab to assess the role of hnRNP A1 in SV positive strand RNA synthesis. RESULTS: hnRNP A1 interacted with the genomic (G) and subgenomic (SG) RNA promoters. Knockdown of hnRNP A1 resulted in markedly decrease in the synthesis of G and SG RNA both in infected cells and in vitro. CONCLUSIONS: Our study provides the first direct evidence that hnRNP A1 actively participates in viral RNA replication and is required for the synthesis of G and SG RNA.

In vitro synthesis of Sindbis virus genomic and subgenomic RNAs: influence of nsP4 mutations and nucleoside triphosphate concentrations.

Two positive-strand mRNAs are made in Sindbis virus-infected cells, the genomic (G) RNA and the subgenomic (SG) RNA. In mosquito cells infected with wild-type (wt) Sindbis virus, the latter is made in excess over the former; however, in cells infected with SVpzf or SVcpc more G RNA is made than SG RNA. Use was made of in vitro systems to investigate the effects of the SVpzf and SVcpc mutations on the synthesis of SG and G RNAs. Our findings indicate that under standard reaction conditions, the SG/G RNA ratio in vitro reflects the ratio of SG to G RNA made in infected mosquito cells. We observed further that the RNA patterns seen in vitro are affected not only by the SVpzf and SVcpc mutations but also by the nucleoside triphosphate concentrations in the reaction mixtures and that introduction of these mutations into nsP4 and the promoter/template change the relative amounts of SG and G RNAs that are made, likely through the choice of promoter. We conclude that with respect to the SVpzf and SVcpc mutations, it is mainly the nucleotide changes in the SG promoter, not the amino acid changes in nsP4, that determine the SG/G RNA ratio that results. Further, it was observed that the SVpzf mutations enhance the in vitro synthesis of SG RNA at the lowest concentrations of UTP/CTP and that the single SVcpc mutation enhances the synthesis of G RNA at the lowest concentrations of CTP tested. We also identified three Arg residues in nsP4, R545, R546, and R547, that are needed for the synthesis of G RNA but not SG RNA.

hnRNP A1 interacts with the 5' untranslated regions of enterovirus 71 and Sindbis virus RNA and is required for viral replication.

Heterogeneous nuclear ribonucleoprotein (hnRNP) A1 is involved in pre-mRNA splicing in the nucleus and translational regulation in the cytoplasm. The cytoplasmic redistribution of hnRNP A1 is a regulated process during viral infection and cellular stress. Here we demonstrate that hnRNP A1 not only is an internal ribosome entry site (IRES) trans-acting factor that binds specifically to the 5' untranslated region (UTR) of enterovirus 71 (EV71) and regulates IRES-dependent translation but also binds to the 5' UTR of Sindbis virus (SV) and facilitates its translation. The cytoplasmic relocalization of hnRNP A1 in EV71-infected cells leads to the enhancement of EV71 IRES-mediated translation, and its function can be substituted by hnRNP A2, whereas the cytoplasmic relocalization of hnRNP A1 following SV infection enhances the SV translation, but this function cannot be replaced by hnRNP A2. Our study provides the first direct evidence that the cytoplasmic relocalization of hnRNP A1 controls not only the IRES-dependent but also non-IRES-dependent translation initiations of RNA viruses.

Synthesis of genomic and subgenomic RNA in mosquito cells infected with two Sindbis virus nsP4 mutants: influence of intracellular nucleoside triphosphate concentrations.

Cells infected with Sindbis virus (SV) make two positive-strand RNAs, a genomic-length RNA (G) RNA and a subgenomic (SG) RNA. In cells infected with SVstd, and in general in cells infected with wt alphaviruses, more SG RNA is made than G RNA. How the balance between synthesis of G RNA and SG RNA is regulated is not known. SVpzf and SVcpc are nsP4 mutants of SV which, in mosquito cells, make more G RNA than SG RNA. When low concentrations of pyrazofurin (inhibits the synthesis of UTP and CTP) were added to SVpzf-infected cells, the yield of virus was increased, and the ratio of SG/G RNA was changed from <1 to >1. These effects were reversed by uridine. In SVcpc-infected cells, but not in SVstd-infected cells, synthesis of viral RNA was inhibited by the addition of either uridine or cytidine, and viral yields were lowered. Our findings suggest that the activities of the viral RNA-synthesizing complexes in cells infected with SVpzf or SVcpc, in contrast to those in SVstd-infected cells, are sensitive to high concentrations of UTP or CTP. Using a cell-free system that synthesizes both SG and G RNA, we measured viral RNA synthesis as a function of the UTP/CTP concentrations. The results indicated that the presence of the SVpzf mutations in nsP4 and the SG promoter produced a pattern quite different from that seen with the SVstd nsP4 and SG promoter. As the UTP/CTP concentrations were increased, the SVpzf system, in contrast to the SVstd system, made more G RNA than SG RNA, reflecting the situation in cells infected with SVpzf.

Viral protein synthesis is required for Enterovirus 71 to induce apoptosis in human glioblastoma cells.

Human glioblastoma cells (SF268) develop apoptosis, as characterized by DNA fragmentation and caspase activation, upon infection with Enterovirus 71 (EV71). To determine the step in virus replication that triggers apoptosis, the authors used ultraviolet (UV)-inactivated virus, inhibitors of protein and viral RNA synthesis, and chloroquine to block virus uncoating. Activation of caspase-3 was detected 24 h after infection with EV71 but not with UV-inactivated EV71. Apoptosis was inhibited when EV71-infected cells were treated with chloroquine, guanidine HCl, or cycloheximide. In summary, the authors studied the event(s) required to induce apoptosis in EV71-infected human glioblastoma cells, a subject much less studied than the possible role of viral proapoptotic genes, concluding that EV71 induces apoptosis in the infected SF268 cell in the presence of viral protein synthesis and virus replication, whereas virus adsorption, internalization, entry, uncoating, and viral RNA replication are all not required to trigger the apoptosis.

Distinct sites on the Sindbis virus RNA-dependent RNA polymerase for binding to the promoters for the synthesis of genomic and subgenomic RNA.

Sindbis virus-infected cells make two positive-strand RNAs, a genomic (G) RNA and a subgenomic (SG) RNA. Here we report the amino acid sequence in nonstructural protein 4 (nsP4), the viral RNA-dependent RNA polymerase, that binds to the promoter for the synthesis of G RNA. In addition, using a cell-free system that makes both G and SG RNA, we show that specific amino acid changes in nsP4 that abolish the synthesis of SG RNA have no effect on the synthesis of G RNA. Our findings indicate that nsP4 has distinct sites for the recognition of the G and SG promoters.

Antiviral therapy targeting viral polymerase.

Viral DNA and RNA polymerases are enzymes, which are responsible for copying the genetic materials of viruses and are therefore central components in the life cycles of viruses. The polymerases are essentially required for the replication of viruses. The reverse transcriptase (RT) of the retroviruses and the hepadnaviruses is the sole viral enzyme required for the synthesis of DNA from viral RNA. Viral polymerases are therefore an extremely favorable target for the development of antiviral therapy. The success of anti-HIV-1 therapy using inhibitors specifically targeting HIV RT suggests that other viral polymerases can be the valid molecular targets for the design of antiviral drugs. Intensive structural and functional studies of viral polymerases have been conducted and have opened new avenues for the development of more effective antiviral therapy. This review summarizes the insights gained from recent structural and functional studies of antiviral agents, which target viral polymerases. The primary focus will be on hepatitis C virus (HCV), herpesviruses, HIV, hepatitis B virus (HBV) and influenza virus.

A cell-free system for the synthesis of Sindbis virus subgenomic RNA: importance of the concentration of the initiating NTP.

We describe here an in vitro system for template-dependent initiation and synthesis of a Sindbis virus (SV) subgenomic (SG) RNA transcript. The critical components of this system were (1) a minus-strand promoter-template corresponding to the region of the SV genome from nt 7441 to nt 7772 (-157 to +175 relative to the SG RNA transcription initiation site at nt 7598), and (2) a p15 fraction from cells infected with recombinant vaccinia viruses expressing the SV nonstructural proteins, P123 and nsP4 (the nsP2 coding region in P123 contained a mutation which results in more rapid than normal processing of P123). Our data indicate that the SG RNA transcript is of the expected size, of positive polarity, and is initiated at the expected site. Changing the +1 nt from A to G, U, or C resulted in decreased synthesis of the SG RNA transcript. However, in each case, increasing the concentration of the initiating NTP restored synthesis of the transcript to the wild-type level. This is the first demonstration of an in vitro synthesis of an alphavirus SG RNA transcript which is dependent on the addition of an exogenous promoter-template. As such, it will make possible new approaches for learning how the synthesis of SG RNA is regulated.

Identification of genes involved in the host response to enterovirus 71 infection.

Enterovirus 71 (EV71) infection may be asymptomatic or may cause diarrhea, rashes, and hand, foot, and mouth disease (HFMD). However, EV71 also has the potential to cause severe neurological disease. To date, little is known about the molecular mechanisms of host response to EV71 infection. In this report, we utilized cDNA microarray to profile the kinetics and patterns of host gene expression in EV71-infected human neural SF268 cells. We have identified 157 genes with significant changes in mRNA expression and performed hierarchical clustering to classify these genes into five different groups based on their kinetics of expression. EV71 infection led to increases in the level of mRNAs encoding chemokines, proteins involved in protein degradation, complement proteins, and proapoptotis proteins. cDNA microarray expression comparisons of EV71- and mock-infected cells also revealed the down-regulation of several genes encoding proteins involved in host RNA synthesis. Expression of interferon-regulated proteins was increased early in the infection and then decreased. Expression of proteins involved in cellular development and differentiation, some oncogenes, and transcription and translation regulators were suppressed and then stimulated late in the infection. Our findings illustrate the overall host response to EV71 infection, and will aid in understanding the host response to this virus.

A mutant of Sindbis virus which is able to replicate in cells with reduced CTP makes a replicase/transcriptase with a decreased Km for CTP.

We reported earlier the isolation and characterization of a Sindbis virus mutant, SV(PZF), that can grow in mosquito cells treated with pyrazofurin (PZF), a compound that interferes with pyrimidine biosynthesis (Y. H. Lin, P. Yadav, R. Ravatn, and V. Stollar, Virology 272:61-71, 2000; Y. H. Lin, H. A. Simmonds, and V. Stollar, Virology 292:78-86, 2002). Three amino acid changes in nsP4, the viral RNA polymerase, were required to produce this phenotype. We now describe a mutant of Sindbis virus, SVCPC, that is resistant to cyclopentenylcytosine (CPC), a compound that interferes only with the synthesis of CTP. Thus, in contrast to SVPZF, which was selected for its ability to grow in mosquito cells with low levels of UTP and CTP, SVCPC was selected for its ability to grow in cells in which only the level of CTP was reduced. Although SV(PZF) was cross-resistant to CPC, SVCPC was not resistant to PZF. Only one amino acid change in nsP4, Leu 585 to Phe, was required for the CPC resistance phenotype. The viral replicase/transcriptase generated in SVCPC-infected mosquito cells had a lower Km for CTP (but not for UTP) than did the enzyme made in SVSTD-infected mosquito cells. SV(PZF) and SVCPC represent the first examples of viral mutants selected for the ability to grow in cells with low levels of ribonucleoside triphosphates (rNTPs). Further study of these mutants and determination of the structure of nsP4 should demonstrate how alterations in an RNA-dependent RNA polymerase permit it to function in cells with abnormally low levels of rNTPs.

Identification of the amino acid sequence in Sindbis virus nsP4 that binds to the promoter for the synthesis of the subgenomic RNA.

A gel mobility-shift assay was used to demonstrate the binding of the Sindbis virus transcriptase to the promoter for the synthesis of subgenomic (SG) RNA. The assay made use of a P15 fraction (the cell fraction that is pelleted at 15,000 x g) from cells infected with recombinant vaccinia virions expressing various Sindbis virus nonstructural proteins (nsPs) and a (32)P-labeled 24-mer oligoribonucleotide representing the minimal sequence with SG promoter activity. By itself, nsP4, the viral RNA-dependent RNA polymerase, did not bind to the SG promoter; rather, all four nsPs were required for the binding of the transcriptase to the promoter. UV crosslinking of the transcriptase to a thiouridine-containing SG promoter, followed by V8 protease digestion of the complex, generated a peptide fragment that was bound to the SG promoter. This peptide fragment contained a sequence that corresponded to residues 329-334 of nsP4. This peptide may be in the fingers domain of nsP4. The peptide that was identified contained Arg residues at positions 331 and 332. Another Arg is present at position 327. By changing each of the Arg residues to Ala, we demonstrated that only the Arg residues at positions 331 and 332 were required for binding nsP4 to the SG promoter.

Alphaviruses and apoptosis.

Many reports have indicated that infection with SV or SFV induces apoptosis both in cultured cells and in the CNS of mice. In general, the ability of virus strains to induce apoptosis correlates with their neurovirulence, although both apoptosis and neurovirulence are age dependent, i.e., resistance increases with age. SV can induce apoptosis simply by the process of membrane fusion and entry, by the expression of the envelope proteins, or by the expression of the nonstructural protein, nsP2. However, viral particles are not necessary to activate apoptosis, since transfection with viral RNA or even viral RNA expressing only the nonstructural proteins will result in apoptosis. The cellular pathways involved in alphavirus-induced apoptosis are complex, and much remains poorly understood. Experimental results point to the involvement of both the mitochondrial and the death receptor pathways. To date, there are no reports implicating the ER stress pathway.

Restriction of a Sindbis virus mutant in BHK cells and relief of the restriction by the addition of adenosine.

SV(PZF) is a mutant of Sindbis virus (SV) which we selected on the basis of its ability to replicate in mosquito cells treated with pyrazofurin (PZF), a drug which inhibits pyrimidine nucleotide biosynthesis (Lin et al., 2000, Virology 272, 61-71). Three mutations, A6627U, A7543U, and C7593A, were identified in the nsP4 (the viral RNA polymerase) coding region, which were required for the PZF-resistant phenotype. We report here that SV(PZF) has a second phenotype. Its replication in BHK cells is severely restricted; yields of SV(PZF) from BHK cells are 100- to 1000-fold lower than the yields of standard SV (SV(STD)). However, addition of adenosine to the SV(PZF)-infected cultures completely relieves this restriction and results in yields comparable to those observed with SV(STD). Adenosine has no effect on the yield of SV(STD) from BHK cells. Synthesis of the viral structural proteins is markedly depressed in SV(PZF)-infected BHK cells, as is synthesis of the viral subgenomic (SG) RNA from which these proteins are translated. In contrast, normal amounts of genomic RNA are made. Experiments with mutagenized viruses indicated that the SV(PZF) mutation, C7593A, by itself, was sufficient to produce the restriction phenotype. However, this mutation not only changes Pro 609 of nsP4 to Thr, it also changes the nucleotide at the minus sign5 position of the SG promoter. To evaluate the relative contributions of the change in nsP4 and the change in the SG promoter to the restriction phenotype, we made use of double SG viruses, in which nsP4 and the promoter for the SG RNA which encodes the structural proteins can be changed independent of each other. Our results indicated that both the change in nsP4 and the change in the SG promoter were required to produce the full restriction phenotype. We suggest that the changes in nsP4 and the SG promoter destabilize the RNA initiation complex assembled at the SG promoter and that since ATP is the initiating nucleotide in the SG RNA transcript, the increased level of ATP resulting from the addition of adenosine is able to compensate for this destabilization and restore the synthesis of SG RNA to normal levels.

The 3C protease activity of enterovirus 71 induces human neural cell apoptosis.

The human glioblastoma SF268 cell line was used to investigate the induction of apoptosis by the 3C protease of enterovirus 71 (EV71). Transient expression in these cells of the wild-type 3C protein encoded by EV71 induced morphological alterations typical of apoptosis, including generation of apoptotic bodies. Degradation of cellular DNA in nucleosomes was also observed. When two of the amino acids in the catalytic motif of 3C were changed by mutagenesis, the 3C protein not only lost its proteolytic activity, but also its ability to induce apoptosis in the SF268 cells. Twenty-four hours after 3C transfection, poly(ADP-ribose) polymerase, a DNA repair enzyme, was cleaved, indicating that caspases were activated by the expression of EV71 3C. The 3C-induced apoptosis was blocked by the caspase inhibitors DEVD-fmk and VAD-fmk. Our findings suggest that the proteolytic activity of 3C triggers apoptosis in the SF268 cells through a mechanism involving caspase activation and that this apoptotic pathway may play an important role in the pathogenesis of EV71 infection.