Sindbis Virus-induced Viral Ribonucleic Acid Polymerase

A cytoplasmic structure containing the viral ribonucleic acid (RNA) polymerase has been isolated by sucrose density centrifugation from cells infected with Sindbis virus. Uninfected cells did not contain any such structure. Preliminary experiments indicated that the structure may be associated with membranes. This structure incorporated (3)H-guanosine triphosphate in vitro in the absence of added template. The RNA synthesized in vitro by the enzyme consisted of single-stranded 40S RNA, the ribonuclease-resistant replicative form, and possibly the replicative intermediate form of viral RNA. The products formed in vitro by the enzyme are identical in sedimentation rates to those formed in the infected cells in vivo.     

Replication of Sindbis Virus V. Polyribosomes and mRNA in Infected Cells

Cells infected with wild-type Sindbis virus contain at least two forms of mRNA, 26S and 49S RNA. Sindbis 26S RNA (molecular weight 1.6 x 10(6)) constitutes 90% by weight of the mRNA in infected cells, and is thought to specify the structural proteins of the virus. Sindbis 49S RNA, the viral genome (molecular weight 4.3 x 10(6)), constitutes approximately 10% of the mRNA in infected cells and is thought to supply the remaining viral functions. In cells infected with ts2, a temperature-sensitive mutant of Sindbis virus, the messenger forms also include a third species of RNA with a sedimentation coefficient of 33S and an apparent molecular weight of 2.3 x 10(6). Hybridization-competition experiments showed that 90% of the base sequences in 33S RNA from these cells are also present in 26S RNA. Sindbis 33S RNA was also isolated from cells infected with wild-type virus. After reaction with formaldehyde, this species of 33S RNA appeared to be completely converted to 26S RNA. These results indicate that 33S RNA isolated from cells infected with either wild-type Sindbis or ts2 is not a unique and separate form of Sindbis RNA.     

Heterologous interference in Aedes albopictus cells infected with alphaviruses.

Maximum amounts of 42S and 26S single-stranded viral RNA and viral structural proteins were synthesized in Aedes albopictus cells at 24 h after Sindbis virus infection. Thereafter, viral RNA and protein syntheses were inhibited. By 3 days postinfection, only small quantities of 42S RNA and no detectable 26S RNA or structural proteins were synthesized in infected cells. Superinfection of A. albopictus cells 3 days after Sindbis virus infection with Sindbis, Semliki Forest, Una, or Chikungunya alphavirus did not lead to the synthesis of intracellular 26S viral RNA. In contrast, infection with snowshoe hare virus, a bunyavirus, induced the synthesis of snowshoe hare virus RNA in both A. Ablpictus cells 3 days after Sindbis virus infection and previously uninfected mosquito cells. These results suggested that at 3 days after infection with Sindbis virus, mosquito cells restricted the replication of both homologous and heterologous alphaviruses but remained susceptible to infection with a bunyavirus. In superinfection experiments the the alphaviruses were differentiated on the basis of plaque morphology and the electrophoretic mobility of their intracellular 26S viral RNA species. Thus, it was shown that within 1 h after infection with eigher Sindbis or Chikungunya virus, A. albopictus cells were resistant to superinfection with Sindbis, Chikungunya, Una, and Semliki Forest viruses. Infected cultures were resistant to superinfection with the homologous virus indefinitely, but maximum resistance to superinfection with heterologous alphaviruses lasted for approximately 8 days. After that time, infected cultures supported the replication of heterologous alphaviruses to the same extent as did persistently infected cultures established months previously. However, the titer of heterologous alphavirus produced after superinfection of persistently infected cultures was 10- to 50-fold less than that produced by an equal number of previously uninfected A. albopictus cells. Only a small proportion (8 to 10%) of the cells in a persistently infected culture was capable of supporting the replication of a heterologous alphavirus.     

Intracellular topology and epitope shielding of poliovirus 3A protein

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

Dephosphorylation of HuR Protein during Alphavirus Infection Is Associated with HuR Relocalization to the Cytoplasm

We have demonstrated previously that the cellular HuR protein binds U-rich elements in the 3′ untranslated region (UTR) of Sindbis virus RNA and relocalizes from the nucleus to the cytoplasm upon Sindbis virus infection in 293T cells. In this study, we show that two alphaviruses, Ross River virus and Chikungunya virus, lack the conserved high-affinity U-rich HuR binding element in their 3′ UTRs but still maintain the ability to interact with HuR with nanomolar affinities through alternative binding elements. The relocalization of HuR protein occurs during Sindbis infection of multiple mammalian cell types as well as during infections with three other alphaviruses. Interestingly, the relocalization of HuR is not a general cellular reaction to viral infection, as HuR protein remained largely nuclear during infections with dengue and measles virus. Relocalization of HuR in a Sindbis infection required viral gene expression, was independent of the presence of a high-affinity U-rich HuR binding site in the 3′ UTR of the virus, and was associated with an alteration in the phosphorylation state of HuR. Sindbis virus-induced HuR relocalization was mechanistically distinct from the movement of HuR observed during a cellular stress response, as there was no accumulation of caspase-mediated HuR cleavage products. Collectively, these data indicate that virus-induced HuR relocalization to the cytoplasm is specific to alphavirus infections and is associated with distinct posttranslational modifications of this RNA-binding protein.     

Solubilization and immunoprecipitation of alphavirus replication complexes.

Alphavirus replication complexes that are located in the mitochondrial fraction of infected cells which pellets at 15,000 x g (P15 fraction) were used for the in vitro synthesis of viral 49S genome RNA, subgenomic 26S mRNA, and replicative intermediates (RIs). Comparison of the polymerase activity in P15 fractions from Sindbis virus (SIN)- and Semliki Forest virus (SFV)-infected cells indicated that both had similar kinetics of viral RNA synthesis in vitro but the SFV fraction was twice as active and produced more labeled RIs than SIN. When assayed in vitro under conditions of high specific activity, which limits incorporation into RIs, at least 70% of the polymerase activity was recovered after detergent treatment. Treatment with Triton X-100 or with Triton X-100 plus deoxycholate (DOC) solubilized some prelabeled SFV RIs but little if any SFV or SIN RNA polymerase activity from large structures that also contained cytoskeletal components. Treatment with concentrations of DOC greater than 0.25% or with 1% Triton X-100-0.5% DOC in the presence of 0.5 M NaCl released the polymerase activity in a soluble form, i.e., it no longer pelleted at 15,000 x g. The DOC-solubilized replication complexes, identified by their polymerase activity in vitro and by the presence of prelabeled RI RNA, had a density of 1.25 g/ml, were 20S to 100S in size, and contained viral nsP1, nsP2, phosphorylated nsP3, nsP4, and possibly nsP34 proteins. Immunoprecipitation of the solubilized structures indicated that the nonstructural proteins were complexed together and that a presumed cellular protein of approximately 120 kDa may be part of the complex. Antibodies specific for nsP3, and to a lesser extent antibodies to nsP1, precipitated native replication complexes that retained prelabeled RIs and were active in vitro in viral RNA synthesis. Thus, antibodies to nsP3 bound but did not disrupt or inhibit the polymerase activity of replication complexes in vitro.     

Viral RNAs Associated with Ribosomes in Sindbis Virus-Infected HeLa Cells

Virus specific RNA ribosome complexes were isolated by sucrose density gradient centrifugation of cytoplasmic extracts from HeLa cells infected at 42 C with an RNA(+) mutant (ts2) of Sindbis virus. Viral RNA-ribosome complexes were accumulated by infected cells treated with sodium fluoride and cycloheximide. The RNA-ribosome complexes were characterized by (i) their sensitivity to the action of ribonuclease or ethylenediaminetetraacetic acid, (ii) their density in cesium chloride gradients, and (iii) presence of host ribosomes and viral RNAs. The viral RNAs were isolated and characterized. The results showed that two species of single-stranded RNAs (a 28s and 18 to 15s species) were associated with the complexes. Base composition analysis of the viral RNAs indicated that both species had a higher adenine content than the 42s or 26s forms of viral RNAs. The RNAs associated with the ribosome complexes were virus specific since they annealed with denatured double-stranded RNAs from the infected cells. Little or no 42S RNA was associated with the RNA-ribosome complexes. The results suggest that the 28s and 18 to 15s forms of RNAs may represent viral messenger RNAs.     

Microviscosity of togavirus membranes studied by fluorescence depolarization: influence of envelope proteins and the host cell.

The microviscosities of the hydrophobic regions of the membranes of intact Semliki forest and Sindbis viruses grown on BHK-21 cells, of liposomes derived from the extracted viral lipids, and of protease-treated virions were measured by fluorescence depolorization using the fluorescence probe 1, 6-diphenyl-1,3,5-hexatriene. The intact virus membranes were found to have a higher microviscosity than did virus-derived liposomes, indicating the viral envelope proteins contribute to microviscosity. However, protease-treated virus, devoid of protruding spikes but with residual lipophilic peptide tails, was found to have a microviscosity more similar to that of the intact virus than to that of protein-free liposomes. Sindbis virus grown in BHK-21 cells at 37 C had a much higher microviscosity than did Sindbis virus grown on Aedes albopicuts cells at 22 C. Sindbis virus grwon in A. albopictus and BHK-21 cells also gave higher microviscosity values than did the intact host cells. These data indicate that both the virion proteins and the cellular lipids selected during viral growth and maturation contribute to the increased microviscosity of togavirus membranes.     

RNA dependent RNA polymerase activity associated with the double-stranded RNA virus of Giardia lamblia.

Giardia lamblia, a parasitic protozoan, can contain a double-stranded RNA (dsRNA) virus, GLV (1). We have identified an RNA polymerase activity present specifically in cultures of GLV infected cells. This RNA polymerase activity is present in crude whole cell lysates as well as in lysates from GLV particles purified from the culture medium. The RNA polymerase has many characteristics common to other RNA polymerases (e.g. it requires divalent cations and all four ribonucleoside triphosphates), yet it is not inhibited by RNA polymerase inhibitors such as alpha-amanitin or rifampicin. The RNA polymerase activity synthesizes RNAs corresponding to one strand of the GLV genome, although under the present experimental conditions, the RNA products of the reaction are not full length viral RNAs. The in vitro products of the RNA polymerase reaction co-sediment through sucrose gradients with viral particles; and purified GLV viral particles have RNA polymerase activity. The RNA polymerase activities within and outside of infected cells closely parallel the amount of virus present during the course of viral infection. The similarities between the RNA polymerase of GLV and the polymerase associated with the dsRNA virus system of yeast are discussed.     

Maturation Defects in Temperature-sensitive Mutants of Sindbis Virus

Temperature-sensitive mutants of Sindbis virus, which synthesize viral ribonucleic acid (RNA) but not mature virus at the nonpermissible temperature, were selected for the study of viral maturation. Of these, three mutants which complement each other genetically were used. Two major proteins, the nucleocapsid and membrane proteins, located, respectively, in the viral nucleoid and membrane, were found in intact virions. In cells infected with wild-type Sindbis virus, four distinct types of viral RNA with sedimentation coefficients of 40S, 26S, 20S, and 15S were detected in constant distribution. The 20S RNA was ribonuclease-resistant, whereas the other types were ribonuclease-sensitive. The 40S RNA, identical to that obtained from the virion, was found associated with nucleocapsid protein as a subviral particle, which was assumed to be the nucleoid. Viral materials from cells infected with the mutants under nonpermissive conditions were compared with those from cells infected with wild-type virus, in terms of (i) the distribution of the different types of RNA, (ii) the association of infectious viral RNA into subviral particles, and (iii) the ability of infected cells to hemadsorb goose erythrocytes. According to these criteria, each of the three mutants demonstrated different maturation defects. Defective nucleocapsid proteins and membrane proteins may each account for one of the above mutants. The thrid mutant may have defects in a minor structural protein or possibly a maturation protein which is involved in the assembly of Sindbis virus.     

Deletion mapping of Sindbis virus DI RNAs derived from cDNAs defines the sequences essential for replication and packaging

Defective-interfering (DI) genomes of a virus contain sequence information essential for their replication and packaging. They need not contain any coding information and therefore are a valuable tool for identifying cis-acting, regulatory sequences in a viral genome. To identify these sequences in a DI genome of Sindbis virus, we cloned a cDNA copy of a complete DI genome directly downstream of the promoter for the SP6 bacteriophage DNA dependent RNA polymerase. The cDNA was transcribed into RNA, which was transfected into chicken embryo fibroblasts in the presence of helper Sindbis virus. After one to two passages the DI RNA became the major viral RNA species in infected cells. Data from a series of deletions covering the entire DI genome show that only sequences in the 162 nucleotide region at the 5' terminus and in the 19 nucleotide region at the 3' terminus are specifically required for replication and packaging of these genomes.     

Defective mutant of Sindbis virus with a smaller-molecular-weight form of the E1 glycoprotein.

We have isolated from a single plaque a mutant of Sindbis virus characterized by an E1 glycoprotein with higher electrophoretic mobility. This higher mobility is not attributable to a different extent of glycosylation of the protein nor to an altered proteolytic maturation pathway of the polypeptide precursor, but is the result of a deletion occurring during the replication of the viral RNA. The 26S RNA (the messenger for the Sindbis structural proteins) extracted from cells infected with the mutant is about 0.75 x 10(5) daltons smaller than the 26S RNA from the parental strain. As a consequence, in cells infected with the mutant, an E1 glycoprotein is synthesized with a polypeptide chain about 70 amino acids shorter. The biological relevance of this naturally occurring deletion of the viral genome is discussed.     

Mengovirus Replication in Novikoff Rat Hepatoma and Mouse L Cells: Effects on Synthesis of Host-Cell Macromolecules and Virus-specific Synthesis of Ribonucleic Acid

Novikoff cells (strain N1S1-67) and L-67 cells, a nutritional mutant of the common strain of mouse L cells which grows in the same medium as N1S1-67 cells, were infected with mengovirus under identical experimental conditions. The synthesis of host-cell ribonucleic acid (RNA) by either type of cell was not affected quantitatively or qualitatively until about 2 hr after infection, when viral RNA synthesis rapidly displaced the synthesis of cellular RNA. The rate of synthesis of protein by both types of cells continued at the same rate as in uninfected cells until about 3 hr after infection, and a disintegration of polyribosomes occurred only towards the end of the replicative cycle, between 5 and 6 hr. The time courses and extent of synthesis of single-stranded and double-stranded viral RNA and of the production of virus were very similar in both types of cells, in spite of the fact that the normal rate of RNA synthesis and the growth rate of uninfected N1S1-67 cells are about three times greater than those of L-67 cells. In both cells, the commencement of viral RNA synthesis coincided with the induction of viral RNA polymerase, as measured in cell-free extracts. Viral RNA polymerase activity disappeared from infected L-67 cells during the period of production of mature virus, but there was a secondary increase in activity in both types of cells coincidental with virus-induced disintegration of the host cells. Infected L-67 cells, however, disintegrated and released progeny virus much more slowly than N1S1-67 cells. The two strains of cells also differed in that replication of the same strain of mengovirus was markedly inhibited by treating N1S1-67 cells with actinomycin D prior to infection; the same treatment did not affect replication in L-67 cells.     

Dominant inhibitory Ras delays Sindbis virus-induced apoptosis in neuronal cells.

Mature neurons are more resistant than dividing cells or differentiating neurons to Sindbis virus-induced apoptotic death. Therefore, we hypothesized that mitogenic signal transduction pathways may influence susceptibility to Sindbis virus-induced apoptosis. Since Ras, a 21-kDa GTP-binding protein, plays an important role in cellular proliferation and neuronal differentiation, we investigated the effect of an inducible dominant inhibitory Ras on Sindbis virus-induced death of a rat pheochromocytoma cell line, PC12 cells. Dexamethasone induction of dominant inhibitory Ras (Ha Ras(Asn17)) expression in transfected PC12 cell lines (MMTV-M17-21 and GSrasDN6 cells) resulted in a marked delay in Sindbis virus-induced apoptosis, compared with infected, uninduced cells. The delay in death after Sindbis virus infection in induced versus uninduced PC12 cells was not associated with differences in viral titers or viral infectivity. No delay in Sindbis virus-induced apoptosis was observed in Ha Ras(Asn17)-transfected PC12 cells if dexamethasone induction was initiated less than 12 h before Sindbis virus infection or in wild-type PC12 cells infected with a chimeric Sindbis virus construct that expresses Ha Ras(Asn17). The delay in Sindbis virus-induced apoptosis in induced Ha Ras(Asn17)-transfected PC12 cells was associated with a decrease in cellular DNA synthesis as measured by 5'-bromo-2'-deoxyuridine incorporation. Thus, in PC12 cells, inducible dominant inhibitory Ras inhibits cellular proliferation and delays Sindbis virus-induced apoptosis. These findings suggest that a Ras-dependent signaling pathway is a determinant of neuronal susceptibility to Sindbis virus-induced apoptosis.     

Functional defects of RNA-negative temperature-sensitive mutants of Sindbis and Semliki Forest viruses.

Defects in RNA and protein synthesis of seven Sindbis virus and seven Semliki Forest virus RNA-negative, temperature-sensitive mutants were studied after shift to the restrictive temperature (39 degrees C) in the middle of the growth cycle. Only one of the mutants, Ts-6 of Sindbis virus, a representative of complementation group F, was clearly unable to continue RNA synthesis at 39 degrees C, apparently due to temperature-sensitive polymerase. The defect was reversible and affected the synthesis of both 42S and 26S RNA equally, suggesting that the same polymerase component(s) is required for the synthesis of both RNA species. One of the three Sindbis virus mutants of complementation group A, Ts-4, and one RNA +/- mutant of Semliki Forest virus, ts-10, showed a polymerase defect even at the permissive temperature. Seven of the 14 RNA-negative mutants showed a preferential reduction in 26S RNA synthesis. The 26S RNA-defective mutants of Sindbis virus were from two different complementation groups, A and G, indicating that functions of two viral nonstructural proteins ("A" and "G") are required in the regulation of the synthesis of 26S RNA. Since the synthesis of 42S RNA continued, these functions of proteins A and G are not needed for the polymerization of RNA late in infection. The RNA-negative phenotype of 26S RNA-deficient mutants implies that proteins regulating the synthesis of this subgenomic RNA must have another function vital for RNA synthesis early in infection or in the assembly of functional polymerase. Several of the mutants having a specific defect in the synthesis of 26S RNA showed an accumulation of a large nonstructural precursor protein with a molecular weight of about 200,000. One even larger protein was demonstrated in both Semliki Forest virus- and Sindbis virus-infected cells which probably represents the entire nonstructural polyprotein.