Molecular defects caused by temperature-sensitive mutations in Semliki Forest virus nsP1

Alphavirus replicase protein nsP1 has multiple functions during viral RNA synthesis. It catalyzes methyltransferase and guanylyltransferase activities needed in viral mRNA capping, attaches the viral replication complex to cytoplasmic membranes, and is required for minus-strand RNA synthesis. Two temperature-sensitive (ts) mutations in Semliki Forest virus (SFV) were previously identified within nsP1: ts10 (E529D) and ts14 (D119N). Recombinant viruses containing these individual mutations reproduced the features of the original ts strains. We now find that the capping-associated enzymatic activities of recombinant nsP1, containing ts10 or ts14 lesions, were not ts. The mutant proteins and polyproteins also were membrane bound, mutant nsP1 interacted normally with the other nonstructural proteins, and there was no major defect in nonstructural polyprotein processing in the mutants, although ts14 surprisingly displayed slightly retarded processing. The two mutant viruses were specifically defective in minus-strand RNA synthesis at the restrictive temperature. Integrating data from SFV and Sindbis virus, we discuss the domain structure of nsP1 and the relative positioning of and interactions between the replicase proteins. nsP1 is suggested to contain a specific subdomain involved in minus-strand synthesis and interaction with the polymerase nsP4 and the protease nsP2.     

Enzymatic defects of the nsP2 proteins of Semliki Forest virus temperature-sensitive mutants

We have analyzed the biochemical consequences of mutations that affect viral RNA synthesis in Semliki Forest virus temperature-sensitive (ts) mutants. Of the six mutations mapping in the multifunctional replicase protein nsP2, three were located in the N-terminal helicase region and three were in the C-terminal protease domain. Wild-type and mutant nsP2s were expressed, purified, and assayed for nucleotide triphosphatase (NTPase), RNA triphosphatase (RTPase), and protease activities in vitro at 24°C and 35°C. The protease domain mutants (ts4, ts6, and ts11) had reduced protease activity at 35°C but displayed normal NTPase and RTPase. The helicase domain mutation ts1 did not have enzymatic consequences, whereas ts13a and ts9 reduced both NTPase and protease activities but in different and mutant-specific ways. The effects of these helicase domain mutants on protease function suggest interdomain interactions within nsP2. NTPase activity was not directly required for protease activity. The similarities of the NTPase and RTPase results, as well as competition experiments, suggest that these two reactions utilize the same active site. The mutations were also studied in recombinant viruses first cultivated at the permissive temperature and then shifted up to the restrictive temperature. Processing of the nonstructural polyprotein was generally retarded in cells infected with viruses carrying the ts4, ts6, ts11, and ts13a mutations, and a specific defect appeared in ts9. All mutations except ts13a were associated with a large reduction in the production of the subgenomic 26S mRNA, indicating that both protease and helicase domains influence the recognition of the subgenomic promoter during virus replication.     

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.     

Biogenesis of the Semliki Forest virus RNA replication complex

The nonstructural (ns) proteins nsP1 to -4, the components of Semliki Forest virus (SFV) RNA polymerase, were localized in infected cells by confocal microscopy using double labeling with specific antisera against the individual ns proteins. All ns proteins were associated with large cytoplasmic vacuoles (CPV), the inner surfaces of which were covered by small invaginations, or spherules, typical of alphavirus infection. All ns proteins were localized by immuno-electron microscopy (EM) to the limiting membranes of CPV and to the spherules, together with newly labeled viral RNA. Along with earlier observations by EM-autoradiography (P. M. Grimley, I. K. Berezesky, and R. M. Friedman, J. Virol. 2:326–338, 1968), these results suggest that individual spherules represent template-associated RNA polymerase complexes. Immunoprecipitation of radiolabeled ns proteins showed that each antiserum precipitated the other three ns proteins, implying that they functioned as a complex. Double labeling with organelle-specific and anti-ns-protein antisera showed that CPV were derivatives of late endosomes and lysosomes. Indeed, CPV frequently contained endocytosed bovine serum albumin-coated gold particles, introduced into the medium at different times after infection. With time, increasing numbers of spherules were also observed on the cell surfaces; they were occasionally released into the medium, probably by secretory lysosomes. We suggest that the spherules arise by primary assembly of the RNA replication complexes at the plasma membrane, guided there by nsP1, which has affinity to lipids specific for the cytoplasmic leaflet of the plasma membrane. Endosomal recycling and fusion of CPV with the plasma membrane can circulate spherules between the plasma membrane and the endosomal-lysosomal compartment.     

Proteins synthesized by Semliki Forest virus and its 16 temperature-sensitive mutants.

The proteins synthesized in chicken embryo fibroblasts infected with wild-type Semliki Forest virus and 16 temperature-sensitive mutants derived from it were studied by polyacrylamide gel electrophoresis. In addition to the structural proteins, five nonvirion proteins (NVP) with molecular weight of 130,000, 97,000, 86,000, 78,000 and 62,000 were found varying amounts in cells infected with the different RNA+ mutants and also in the wild-type-infected cells. Pulse-chase experiments suggested that NVP 130, NVP 97, NVP 86, and NVP 62 are precursors presumably of the structural proteins. The amount of NVP 78 was not affected by the chase, and it may represent a translational product of the nonstructural part of the genome. The NVP 130 was shown to be a common precursor of the structural proteins by tryptic peptide mapping. Kinetic evidence from one of the mutants (ts-3) suggested that NVP 86 is one of the precursors of the capsid protein. A common feature of all the RNA+mutants was the inability to cleave the NVP 62 into E2 and E3, suggesting that this cleavage is a crucial reaction in the virus maturation.     

RNA interference-mediated inhibition of Semliki Forest virus replication in mammalian cells

RNA interference (RNAi) has recently shown promise as a mode of inhibition of slowly replicating viruses causing chronic diseases such as hepatitis C. To investigate whether RNAi is also feasible for rapidly growing RNA viruses such as alphaviruses, we tested the ability of expressed short hairpin RNAs (shRNAs) to inhibit the Semliki Forest virus (SFV), a rapidly replicating positive-strand RNA virus. Plasmids expressing shRNAs targeting SFV target sequences under the control of a human U6 promoter were introduced into BHK-21 cells. The targets included sequences encoding nonstructural (nsP1, 2, and 4) and structural (capsid) proteins as well as nonviral sequences serving as control targets. Twenty-four to 48 hours following transfection with shRNA plasmids, the cells were infected with replication-competent or replication-deficient recombinant SFV expressing green fluorescent protein (GFP) at a multiplicity of infection (MOI) of approximately 5. Viral replication was monitored by fluorescence microscopy and flow cytometry. Specific and marked reduction of viral replication was observed with shRNAs targeting nsP1 and nsP4. The degree of inhibition of the replication-deficient SFV was >or=70% over a 5-day period, a level similar to the transfection efficiency, suggesting complete inhibition of nonreplicating virus in the transfected cell population. However, only nsP1 shRNA was inhibitory against replication-competent SFV (approximately 30%-50% reduction), and this effect was transient. No inhibition was observed with control shRNAs. In contrast to the recent success of RNAi approaches for slowly growing viruses, these results illustrate the challenge of inhibiting very rapidly replicating RNA viruses by RNAi. However, the addition of RNAi approaches to other antiviral modalities might improve the response to acute infections.     

Mechanisms of mutations inhibiting fusion and infection by Semliki Forest virus

Semliki Forest virus (SFV) infects cells by an acid-dependent membrane fusion reaction catalyzed by the virus spike protein, a complex containing E1 and E2 transmembrane subunits. E1 carries the putative virus fusion peptide, and mutations in this domain of the spike protein were previously shown to shift the pH threshold of cell-cell fusion (G91A), or block cell-cell fusion (G91D). We have used an SFV infectious clone to characterize virus particles containing these mutations. In keeping with the previous spike protein results, G91A virus showed limited secondary infection and an acid-shifted fusion threshold, while G91D virus was noninfectious and inactive in both cell- cell and virus-liposome fusion assays. During the low pH- induced SFV fusion reaction, the E1 subunit exposes new epitopes for monoclonal antibody (mAb) binding and forms an SDS-resistant homotrimer, the virus associates hydrophobically with the target membrane, and fusion of the virus and target membranes occurs. After low pH treatment, G91A spike proteins were shown to bind conformation-specific mAbs, associate with target liposome membranes, and form the E1 homotrimer. However, both G91A membrane association and homotrimer formation had an acid-shifted pH threshold and reduced efficiency compared to wt virus. In contrast, studies of the fusion-defective G91D mutant showed that the virus efficiently reacted with low pH as assayed by mAb binding and liposome association, but was essentially inactive in homotrimer formation. These results suggest that the G91D mutant is noninfectious due to a block in a late step in membrane fusion, separate from the initial reaction to low pH and interaction with the target membrane, and involving the lack of efficient formation of the E1 homotrimer.     

New types of RNA polymerase mutations causing temperature-sensitive sporulation in bacillus subtilis.

A single site mutant of Bacillus subtilis with a streptovaricin-resistant RNA polymerase has been isolated; this mutation caused temperature-sensitive sporulation, but had no effect on vegetative growth. The mutant (ts710) temperature-sensitive period irreversibly affected the middle and late stages of sporulation. Mutant cells grown at the nonpermissive temperature exhibited abnormal serine protease accumulation, serine esterase accumulation, alkaline phosphatase accumulation, RNA polymerase template specificity changes, and pulse-labeled RNA synthesis profiles. The accumulation of metal protease was not affected at the nonpermissive temperature. Attempts to isolate single site mutants which were streptolydigin-resistant, and temperature-sensitive for sporulation, were unsuccessful.     

Two interacting mutations causing temperature-sensitive phosphatidylglycerol synthesis in Escherichia coli membranes.

A conditionally lethal mutant of Escherichia coli lacking phosphatidylglycerol in vivo at 42 degrees C has been previously isolated by two-stage mutagenesis (M. Nishijima and C. R. H. Raetz, J. Biol. Chem. 254:7837-7844, 1979). In the first step (designated pgsA444) the phosphatidylglycerophosphate synthetase is partially inactivated, but the resulting strain continues to make about two-thirds of the normal level of phosphatidylglycerol and is not temperature sensitive. The second lesion, termed pgsB1, causes temperature-sensitive growth and phosphatidylglycerol synthesis in strains harboring pgsA444. The pgsA locus appears to be the structural gene for the synthetase and maps near min 42. In the present study we mapped the pgsB1 mutation and characterized its interaction with pgsA444 by genetic and biochemical methods. Unexpectedly, pgsB1 was not a second lesion in the pgsA structural gene, but rather mapped at a distinct site near minute 4. P1 vir-mediated contransduction suggested the gene order pantonA-dapD-pgsB-dnaE (clockwise). Independent evidence for the genetic mapping was provided by the identification of two hybrid ColE1 plasmids (pLC26-43 and pLC34-20. L. Clarke and J. Carbon, Cell 9:91-99, 1976) which both carry pgsB+ and dnaE+. Introduction of either the pgsA+ or the pgsB+ gene (via episomes, hybrid plasmids or P1 vir transduction) suppressed the temperature sensitivity of the double mutant (pgsA444 pgsB1) and restored normal levels of phosphatidylglycerol at 42 degrees C. In addition, strains with the pgsA+ pgsB1 genotype produced a novel lipid (X) at all temperatures, whereas the double mutant (pgsA444 pgsB1) contained two unusual lipids (X and Y) after 3 h at 42 degrees C. Both X and Y are precursors of lipopolysaccharide, and introduction of pgsB+ into the double mutant caused the disappearance of X and Y. Although the biochemical basis of the pgsB1 lesion is unknown, its existence suggests a previously unrecognized link between lipopolysaccharide and phosphatidylglycerol syntheses in E. coli.     

Protein-bound oligosaccharides of Semliki Forest virus

Semliki Forest virus was grown in BHK cells and labeled in vivo with radio-active monosaccharides. promnase digenst of the virus chromatographer on Bio-Gel P 6 revealed glycopeptides of A-type and B-type. (For the nomenclature see Johnson J. and Clamp J.R. (1971) Biochem. J. 123, 739–745) The former was labeled with [³H]fucose, [³H]galactose, [³H]mannose and [¹⁴C]glucosamine, the latter only with [³H]mannose and [¹⁴C]glucosamine. The three envelope glycoproteins E₁, E₂ and E₃ were isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and subjected to pronase digestion. The glycoproteins E₁ and E₃ revealed glycopeptides of A-type. E₂ revealed glycopeptides of B-type. E₂ yielded additionally a glycopeptide (M_r3100) which was heavily labeled from [³H]galactose, but only marginally from [¹⁴C]glucosamine, [³H]fucose and [³H]mannose. Wether this glycopeptide belongs to the A-type or not remains uncertain. The apparent molecular weights of the A-type units measured by gel filtration were 3400 in E₁ and 4000 in E₃; the B-type unit of E₂ had an apparent molecular weight of 2000. Combined with the findings of our earlier chemical analysis these data suggast that E₁ and E₃ contain on the average one A-type unit; E₂ probably contains one 3100 dalton unit plus one or two B-type units.     

Initiation of synthesis of the structural proteins of Semliki Forest virus.

Insertion of phage λ DNA into the normal attachment site of the DNA of the host Escherichia coli has been studied by ultracentrifugation analysis of the conversion of covalent circles of F′450 (F′gal att^λ bio) to F′450(λ) circles. We have found that integration proceeds at the normal rate if, in addition to the int gene product and a proper combination of phage and bacterial attachment sites, a large pool of λ DNA and some activity of the excision gene xis are present. In addition, turnoff of both phage DNA synthesis and xis gene activity are required.     

Nairovirus RNA sequences expressed by a Semliki Forest virus replicon induce RNA interference in tick cells

We report the successful infection of the cell line ISE6 derived from Ixodes scapularis tick embryos by the tick-borne Hazara virus (HAZV), a nairovirus in the family Bunyaviridae. Using a recombinant Semliki Forest alphavirus replicon that replicates in these cells, we were able to inhibit replication of HAZV, and we showed that this blockage is mediated by the replication of the Semliki Forest alphavirus replicon; the vector containing the HAZV nucleoprotein gene in sense or antisense orientation efficiently inhibited HAZV replication. Moreover, expression of a distantly related nucleoprotein gene from Crimean-Congo hemorrhagic fever nairovirus failed to induce HAZV silencing, indicating that the inhibition is sequence specific. The resistance of these cells to replicate HAZV correlated with the detection of specific RNase activity and 21- to 24-nucleotide-long small interfering RNAs. Altogether, these results strongly suggest that pathogen-derived resistance can be established in the tick cells via a mechanism of RNA interference.     

Structure of Semliki Forest virus core protein

Alphaviruses are enveloped, insect-borne viruses, which contain a positive-sense RNA genome. The protein capsid is surrounded by a lipid membrane, which is penetrated by glycoprotein spikes. The structure of the Sindbis virus (SINV) (the type virus) core protein (SCP) was previously determined and found to have a chymotrypsin-like structure. SCP is a serine proteinase which cleaves itself from a polyprotein. Semliki Forest virus (SFV) is among the most distantly related alphaviruses to SINV. Similar to SCP, autocatalysis is inhibited in SFCP after cleavage of the polyprotein by leaving the carboxy-terminal tryptophan in the specificity pocket. The structures of two different crystal forms (I and II) of SFV core protein (SFCP) have been determined to 3.0 Å and 3.3 Å resolution, respectively. The SFCP monomer backbone structure is very similar to that of SCP. The dimeric association between monomers, A and B, found in two different crystal forms of SCP is also present in both crystal forms of SFCP. However, a third monomer, C, occurs in SFCP crystal form I. While monomers A and B make a tail-to-tail dimer contact, monomers B and C make a head-to-head dimer contact. A hydrophobic pocket on the surface of the capsid protein, the proposed site of binding of the E2 glycoprotein, has large conformational differences with respect to SCP and, in contrast to SCP, is found devoid of bound peptide. In particular, Tyr184 is pointing out of the hydrophobic pocket in SFCP, whereas the equivalent tyrosine in SCP is pointing into the pocket. The conformation of Tyr184, found in SFCP, is consistent with its availability for iodination, as observed in the homologous SINV cores. This suggests, by comparison with SCP, that E2 binding to cores causes major conformational changes, including the burial of Tyr184, which would stabilize the intact virus on budding from an infected cell. The head-to-tail contacts found in the pentameric and hexameric associations within the virion utilize the same monomer surface regions as found in the crystalline dimer interfaces. Proteins 27:345–359, 1997. © 1997 Wiley-Liss, Inc.     

Protein-bound oligosaccharides of Semliki Forest virus.

Semliki Forest virus was grown in BHK cells and labeled in vivo with radioactive monosaccharides. Pronase digests of the virus chromatographed on Bio-Gel P6 revealed glycopeptides of A-type and B-type. (For the nomenclature see Johnson, J. and Clamp, J.R. (1971) Biochem. J. 123, 739-745.) The former was labeled with [3H]fucose, [3H]galactose, [3H]mannose and [14C]glucosamine, the latter only with [3H]mannose and [14C]glucosamine. The three envelope glycoproteins E1, E2 and E3 were isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and subjected to pronase digestion. The glycoproteins E1 and E3 revealed glycopeptides of A-type. E2 revealed glycopeptides of B-type. E2 yielded additionally a glycopeptide (Mr3100) which was heavily labeled from [3H]galactose, but only marginally from [14C]glucosamine, [3H]fucose and [3H]mannose. Whether this glycopeptide belongs to the A-type or not remains uncertain. The apparent molecular weights of the A-type units measured by gel filtration were 3400 in E1 and 4000 in E3; the B-type unit of E2 had an apparent molecular weight of 2000. Combined with the findings of our earlier chemical analysis these data suggest that E1 and E3 contain on the average one A-type unit; E2 probably contains one 3100 dalton unit plus one or two B-type units.     

Membrane fusion mutants of Semliki Forest virus

Previous reports have indicated that the entry of Semliki Forest virus (SFV) into cells depends on a membrane fusion reaction catalyzed by the viral spike glycoproteins and triggered by the low pH prevailing in the endosomal compartment. In this study the in vitro pH-dependent fusion of SFV with nuclease-filled liposomes has been used to select for a new class of virus mutants that have a pH-conditional defect. The mutants obtained had a threshold for fusion of pH 5.5 as compared with the wild- type threshold of 6.2, when assayed by polykaryon formation, fusion with liposomes, or fusion at the plasma membrane. They were fully capable of infecting cells under standard infection conditions but were more sensitive to lysosomotropic agents that increase the pH in acidic vacuoles of the endocytic pathway. The mutants were, moreover, able to penetrate and infect baby hamster kidney-21 cells at 20 degrees C, indicating that the endosomes have a pH below 5.5. The results confirm the involvement of pH-triggered fusion in SFV entry, emphasize the central role played by acidic endosomal vacuoles in this reaction, shed further light on the mechanism of SFV inhibition by lysosomotropic weak bases, and demonstrate the usefulness of mutant viruses as biological pH probes of the endocytic pathway.