Evaluation of cis-acting elements in the rubella virus subgenomic RNA that play a role in its translation.

The subgenomic (SG) mRNA of rubella virus (RUB) contains the structural protein open reading frame (SP-ORF) that is translated to produce the three virion structural proteins: capsid (C) and glycoproteins E2 and E1. RUB expression vectors have been developed that express heterologous genes from the SG RNA, including replicons which replace the SP-ORF with a heterologous gene, and these expression vectors are candidate vaccine vectors. In the related alphaviruses, translational enhancing elements have been identified in both the 5' untranslated region (UTR) of the SG RNA and the N-terminal region of the C gene. To optimize expression from RUB vectors, both the 5'UTR of the SG RNA and the C gene were surveyed for translational enhancing elements using both plasmids and replicons expressing reporter genes from the SG RNA. In replicons, the entire 5'UTR was necessary for translation; interestingly, when plasmids were used the 5'UTR was dispensable for optimal translation. The RUB C gene contains a predicted long stem-loop starting 62 nts downstream from the initiation codon (SLL) that has a structure and stability similar to SL's found in the C genes of two alphaviruses, Sindbis virus (SIN) and Semliki Forest virus, that have been shown to enhance translation of the SG RNA in infected cells. However, a series of fusions of various lengths of the N-terminus of the RUB C protein with reporter genes showed that the SLL had an attenuating effect on translation that was overcome by mutagenesis that destabilized the SLL or by adding downstream sequences of the C gene to the fusion. Thus, for optimal expression efficiency from RUB expression vectors, only the 5'UTR of the SG RNA is required. Further investigation of the differing effects of the SLL on RUB and alphavirus SG RNA translation revealed that the SIN and RUB SLLs could enhance translation when expressed from a SIN cytopathic replicon, but not when expressed from a plasmid, a RUB replicon, or a SIN noncytopathic replicon. Thus, the SLL only functions in a "cytopathic environment" in which cell translation has been altered.

Characterization of genotype II Rubella virus strains.

Two genotypes of Rubella virus have been described that differ by 8-9% at the nucleotide level in the E1 glycoprotein gene. Of these, genotype II (RGII) was only recently reported and in this study two RGII viruses, the BRDII vaccine strain and BR1 wild type strain, were characterized. Monoclonal antibodies against each of the virion proteins (capsid [C], glycoproteins E1 and E2) and polyclonal anti-rubella virus sera reacted similarly with purified virions from the RGII and reference RGI strains on Western gels, with the exception of one anti-E2 Mab, and thus the two genotypes are closely related antigenically. The genomic sequences of two genotype II (RGII) rubella virus strains were determined and compared with the six previously reported RGI sequences. The genomes of these viruses all contained 9762 nts and the lengths of the three untranslated regions (UTRs) and two open reading frames (ORF's) were identical. The overall difference between the RGI and RGII sequences at the nt level was approximately 8% and this difference was maintained across most of the genome. At the amino acid level, the RGI and RGII sequences differed overall by approximately 4%, however this difference was not uniform across the ORF's as the N-terminal third of P150 and the entirety of P90, both replicase proteins, were more conserved (<1% difference) while the C-terminal two thirds of P150 exhibited greater variation ( approximately 8% difference), including a hypervariable region between residues 771-801 within which divergence as great as 20-30% was detected. The parent wt virus of the BRDII vaccine was not available and its sequence was compared with the BR1 sequence to identify potential attenuating mutations. The BRDII and BR1 sequences varied at 252 residues (2.59%), including twelve in the UTRs and thirty coding differences in the ORF's. None of these differences in the BRDII sequence was vaccine-specific when compared with RGI wt and vaccine sequences and, therefore, there appeared to be no common pathway in the generation of live, attenuated rubella vaccines.

Rubella virus DI RNAs and replicons: requirement for nonstructural proteins acting in cis for amplification by helper virus.

A rubella virus (RUB) replicon was constructed by replacing the 3' proximal structural protein ORF (SP-ORF) in Robo402, a RUB infectious cDNA clone, with a reporter gene, green fluorescent protein (GFP). This replicon, RUBrep/GFP, mimics naturally occurring RUB defective-interfering (DI) RNAs generated during serial undiluted passage that maintain the 5' proximal nonstructural protein ORF (NS-ORF) but contain deletions in the SP-ORF. Following transfection of Vero cells with in vitro RNA transcripts from RUBrep/GFP, replicon replication occurred and the replicon was amplified and spread to other cells in the presence of standard helper virus. GFP expression was a much more sensitive indicator of replicon replication than was Northern analysis to detect replicon-specific RNAs. Most of a series of RUBrep/GFP constructs with deletions in the NS-ORF not only were incapable of self-replication, but were not amplified by standard helper virus. The only exception was a construct with an in-frame deletion between two NotI sites that removed nucleotides 1685-2192 of the genome; this construct did not express GFP by itself, but did express GFP in the presence of standard helper RUB and was spread to other cells. Thus, with the exception of this region, the NS-ORF is required in cis for amplification of RUB replicons by standard helper virus, explaining the selection of DI RNAs that maintain the NS-ORF. Surprisingly, when the NotI deletion was introduced into Robo402, a viable virus resulted that replicated only threefold less efficiently than did Robo402 virus. Thus, the NotI region of the NS-ORF is not necessary for virus replication. This deletion covers a region of the NS-ORF without predicted function, which therefore may function as a spacer or hinge between functional domains. Nevertheless, it was an unexpected finding that a small virus such as RUB could dispense with approximately 10% of its genome.

Development of a rubella virus vaccine expression vector: use of a picornavirus internal ribosome entry site increases stability of expression.

Rubella virus (RUB) is a small plus-strand RNA virus classified in the Rubivirus genus of the family Togaviridae. Live, attenuated RUB vaccines have been successfully used in vaccination programs for over 25 years, making RUB an attractive vaccine vector. In this study, such a vector was constructed using a recently developed RUB infectious cDNA clone (Robo). Using a standard strategy employed to produce expression and vaccine vectors with other togaviruses, the subgenomic promoter was duplicated to produce a recombinant construct (termed dsRobo) that expressed reporter genes such as chloramphenicol acetyltransferase and green fluorescent protein (GFP) under control of the second subgenomic promoter. However, expression of the reporter genes, as exemplified by GFP expression by dsRobo/GFP virus, was unstable during passaging, apparently due to homologous recombination between the subgenomic promoters leading to deletion of the GFP gene. To improve the stability of the vector, the internal ribosome entry site (IRES) of a picornavirus, encephalomyocarditis virus, was used instead of the second subgenomic promoter to eliminate homology. Construction was initiated by first replacing the subgenomic promoter in the parent Robo infectious clone with the IRES. Surprisingly, viable virus resulted; this virus did not synthesize a subgenomic RNA. The subgenomic promoter was then reintroduced in an orientation such that a single subgenomic RNA was produced, GFP was the initial gene on this RNA, while the RUB structural protein open reading frame was downstream and under control of the IRES element. GFP expression by this vector was significantly improved in comparison to dsRobo/GFP. This strategy should be applicable to increase the stability of other togavirus vectors.

Expression of the hepatitis E virus ORF1.

Hepatitis E virus (HEV) is an unclassified, plus-strand RNA virus whose genome contains three open reading frames (ORFs). ORF1, the 5' proximal ORF of HEV, encodes nonstructural proteins involved in RNA replication which share homology with the products of the corresponding ORF of members of the alphavirus-like superfamily of plus-strand RNA viruses. Among animal virus members of this superfamily (the alphavirus and rubivirus genera of the family Togaviridae), the product of this ORF is a nonstructural polyprotein (NSP) that is cleaved by a papain-like cysteine protease (PCP) within the NSP. To determine if the NSP of HEV is similarly processed, ORF1 was introduced into a plasmid vector which allowed for expression both in vitro using a coupled transcription/translation system and in vivo using a vaccinia virus-driven transient expression system. A recombinant vaccinia virus expressing ORF1 was also constructed. Both in vitro and in vivo expression under standard conditions yielded only the full-length 185 kDa polyprotein. Addition of co-factors in vitro, such as divalent cations and microsomes which have been shown to activate other viral proteases, failed to change this expression pattern. However, in vivo following extended incubations (24-36 hours), two potential processing products of 107 kDa and 78 kDa were observed. N- and C-terminus-specific immunoprecipitation and deletion mutagenesis were used to determine that the order of these products within the NSP is NH2-78 kDa-107 kDa-COOH. However, site-specific mutagenesis of Cys483, predicted by computer alignment to be one member of the catalytic dyad of a PCP within the NSP, failed to abolish this cleavage. Additionally, sequence alignment across HEV strains revealed that the other member of the proposed catalytic dyad of this PCP, His590, was not conserved. Thus, the cleavage of the NSP observed following prolonged in vivo expression was not mediated by this protease and it is doubtful that a functional PCP exists within the NSP. Attempts to detect NSP expression and processing in HEV-infected primary monkey hepatocytes were not successful and therefore this proteolytic cleavage could not be authenticated. Overall, the results of this study indicate that either the HEV NSP is not processed or that it is cleaved at one site by a virally-encoded protease novel among alpha-like superfamily viruses or a cellular protease.

Infectious cDNA clone of the RA27/3 vaccine strain of Rubella virus.

Rubella virus (RUB), a small plus-strand RNA virus, is a significant human pathogen. The RA27/3 vaccine strain of RUB is one of the most successful live attenuated vaccines developed. In this article, we report the construction of an RA27/3 infectious clone, a complete cDNA copy of the RA27/3 genome that can be transcribed in vitro to generate infectious RNA molecules. Virus generated from such in vitro transcripts was phenotypically similar to RA27/3 virus. To investigate the attenuation of the RA27/3 strain, a series of chimeras was made by the insertion of different fragments of the RA27/3 genome into an infectious clone based on the Therien wild-type strain of RUB. Analysis of the resulting chimeric viruses revealed that the pattern of RA27/3 attenuation in cell culture is complex: attenuating elements in the RA27/3 genome were found in the 5' untranslated region (UTR), a region of the nonstructural proteins containing the protease motif and the capsid gene. Within the 5' UTR, the attenuation determinant was mapped to nt 7. Surprisingly, these analyses also revealed a potentiating mutation at nt 164 of the RA27/3 genome. Although this determinant was within the coding sequences of the nonstructural proteins, the encoded amino acid had no effect on cell culture phenotype and thus the determinant may operate at the level of RNA structure. In addition to investigation of the mechanisms of RA27/3 attenuation, the availability of the RA27/3 infectious clone offers the opportunity for strict genetic control over RUB vaccine manufacturing, for development of novel DNA-based vaccines against RUB, and for development of recombinant RUB vaccines that also target other diseases.

Characterization of the zinc binding activity of the rubella virus nonstructural protease.

The rubella virus (RUB) nonstructural (NS) protein (NSP) ORF encodes a protease that cleaves the NSP precursor (240 kDa) at a single site to produce two products. A cleavage site mutation was introduced into a RUB infectious cDNA clone and found to be lethal, demonstrating that cleavage of the NSP precursor is necessary for RUB replication. Based on computer alignments, the RUB NS protease was predicted to be a papain-like cysteine protease (PCP) with the residues Cys1152 and His1273 as the catalytic dyad; however, the RUB NS protease was recently found to require divalent cations such as Zn, Co, and Cd for activity (X. Liu, S. L. Ropp, R. J. Jackson, and T. K. Frey, J. Virol. 72:4463-4466, 1998). To analyze the function of metal cation binding in protease activity, Zn binding studies were performed using the minimal NS protease domain within the NSP ORF. When expressed as a maltose binding protein (MBP) fusion protein by bacteria, the NS protease exhibited activity both in the bacteria and in vitro following purification when denatured and refolded in the presence of Zn. Atomic absorption analysis detected 1.6 mol of Zn bound per mol of protein refolded in this manner. Expression of individual domains within the protease as MBP fusions and analysis by a Zn(65) binding assay revealed two Zn binding domains: one located at a predicted metal binding motif beginning at Cys1175 and the other one close to the cleavage site. Mutagenesis studies showed that Cys1175 and Cys1178 in the first domain and Cys1227 and His1273, the His in the predicted catalytic site, in the second domain are essential for zinc binding. All of these residues are also necessary for the protease activity, as were several other Cys residues not involved in Zn binding. Far-UV circular dichroism (CD) analysis of the MBP-NS protease fusion protein showed that the protease domain contained a large amount of alpha-helical structure, which is consistent with the results of secondary-structural prediction. Both far-UV-CD and fluorescence studies suggested that Zn did not exert a major effect on the overall structure of the fusion protein. Finally, protease inhibitor assays found that the protease activity can be blocked by both metal ion chelators and the metalloprotease inhibitor captopril. In conjunction with the finding that the previously predicted catalytic site, His1273, is essential for zinc binding, this suggests that the RUB NS protease is actually a novel virus metalloprotease rather than a PCP.

Development of a rubella virus DNA vaccine.

Two rubella virus DNA vaccines were constructed from a cDNA clone of the rubella virus genomic RNA, one which contained the coding sequences for all three virion proteins (C, E2 and E1) and one which contained the two envelope glycoproteins (E2 and E1). When used to immunize mice via gene gun delivery, both constructs induced an antibody response of equivalent titer to that induced by rubella virus that persisted for at least seven months. A booster injection given four weeks after the initial injection increased antibody titers by over thirty-fold. The antibody response in DNA vaccine-injected mice was directed primarily against the E1 glycoprotein, as was the case in rubella virus-injected mice, and neutralizing activity was detected. These DNA vaccines are thus prototypes for a nonreplicating rubella virus vaccine that could be used in specialized circumstances.

Mutagenic analysis of the 3' cis-acting elements of the rubella virus genome.

Thermodynamically predicted secondary structure analysis of the 3'-terminal 305 nucleotides (nt) of the rubella virus (RUB) genome, a region conserved in all RUB defective interfering RNAs, revealed four stem-loop (SL) structures; SL1 and SL2 are both located in the E1 coding region, while SL3 and SL4 are within the 59-nt 3' untranslated region (UTR) preceding the poly(A) tract. SL2 is a structure shown to interact with human calreticulin (CAL), an autoantigen potentially involved in RUB RNA replication and pathogenesis. RNase mapping indicated that SL2 and SL3 are in equilibrium between two conformations, in the second of which the previously proposed CAL binding site in SL2, a U-U bulge, is not formed. Site-directed mutagenesis of the 3' UTR with a RUB infectious clone, Robo302, revealed that most of the 3' UTR is required for viral viability except for the 3'-terminal 5 nt and the poly(A) tract, although poly(A) was rapidly regenerated during subsequent replication. Maintenance of the overall SL3 structure, the 11-nt single-stranded sequence between SL3 and SL4, and the sequences forming SL4 were all important for viral viability. Studies on the interaction between host factors and the 3' UTR showed the formation of three RNA-protein complexes by gel mobility shift assay, and UV-induced cross-linking detected six host protein species, with molecular masses of 120, 80, 66, 55, 48, and 36 kDa, interacting with the 3' UTR. Site-directed mutagenesis of SL2 by nucleotide substitutions showed that maintenance of SL2 stem rather than the U-U bulge was critical in CAL binding since mutants having the U-U bulge base paired had a similar binding activity for CAL as the native structure whereas mutants having the SL2 stem destabilized had much lower binding activity. However, all of these mutations gave rise to viable viruses when introduced into Robo302, indicating that binding of CAL to SL2 is independent of viral viability.

Rubella virus induces apoptosis in culture cells.

The replication of rubella virus (RUB) in Vero cells, an adherent cell line, results in apoptotic death of infected cells as detected by chromatin fragmentation assays. In infected cultures, virtually all of the cells that had become detached (a hallmark feature of RUB-induced cytopathology) were apoptotic; they were predominantly dead as shown by propidium iodide and trypan blue exclusion tests. In contrast, the majority of the cells in the infected monolayers that remained adherent were alive and contained intact chromatin. Thus simple counting of detached cells in the medium is a convenient way of measuring the extent of RUB-induced apoptosis. RUB-induced cytopathology was inhibited by z-VAD-fmk, an inhibitor of caspases that are involved in the execution stages of apoptosis, confirming the induction of apoptosis by RUB. The lack of apoptotic adherent cells (maximally 1% at any time point through 6 days postinfection) indicates that the induction of apoptosis is asynchronous since cells become uniformly virus antigen-positive by day 2 postinfection. To elucidate whether this asynchronicity and the ability of RUB to persistently infect Vero cells were due to a suppression of apoptosis, we examined whether RUB can suppress chemically induced apoptosis. Staurosporine (ST) was found to be an efficient inducer of apoptosis in Vero cells. ST treatment of RUB-infected and RUB persistently infected cells resulted in a much higher proportion of detached cells, higher even than in Vero cells treated with ST alone. This indicates that RUB does not suppress ST-induced apoptosis and, rather, that ST and RUB acted cumulatively in inducing apoptosis, possibly indicating that they use different induction pathways.

Molecular analysis of rubella virus epidemiology across three continents, North America, Europe, and Asia, 1961-1997.

E1 gene nucleotide sequences of 63 rubella virus isolates from North America, Europe, and Asia isolated between 1961 and 1997 were compared phylogenetically. Two genotypes were evident: Genotype I contained 60 viruses from North America, Europe, and Japan, and genotype II contained 3 viruses from China and India. The genotype I isolates prior to 1970 grouped into a single diffuse clade, indicating intercontinental circulation, while most post-1975 viruses segregated into geographic clades from each continent, indicating evolution in response to vaccination programs. The E1 amino acid sequences differed by no more than 3%; thus, no major antigenic variation was apparent. Among 4 viruses from congenital rubella syndrome that occurred following reinfection, only one amino acid substitution occurred in several important epitopes, indicating that antigenic drift is not important in this phenomenon. However, 2 viruses isolated from chronic arthritis exhibited changes in these epitopes. Isolates of the RA 27/3 vaccine strain were readily identifiable by nucleotide sequence.

The rubella virus nonstructural protease requires divalent cations for activity and functions in trans.

The rubella virus (RUB) nonstructural (NS) protease is a papain-like cysteine protease (PCP) located in the NS-protein open reading frame (NSP-ORF) that cleaves the NSP-ORF translation product at a single site to produce two products, P150 (the N-terminal product) and P90 (the C-terminal product). The RUB NS protease was found not to function following translation in vitro in a standard rabbit reticulocyte lysate system, although all of the other viral PCPs do so. However, in the presence of divalent cations such as Zn2+, Cd2+, and Co2+, the RUB NS protease functioned efficiently, indicating that these cations are required either as direct cofactors in catalytic activity or for correct acquisition of three-dimensional conformation of the protease. Since other viral and cell PCPs do not require cations for activity and the RUB NS protease contains a putative zinc binding motif, the latter possibility is more likely. Previous in vivo expression studies of the RUB NS protease failed to demonstrate trans cleavage activity (J.-P. Chen et al., J. Virol. 70:4707-4713, 1996). To study whether trans cleavage could be detected in vitro, a protease catalytic site mutant and a mutant in which the C-terminal 31 amino acids of P90 were deleted were independently introduced into plasmid constructs that express the complete NSP-ORF. Cotranslation of these mutants in vitro yielded both the native and the mutated forms of P90, indicating that the protease present in the mutated construct cleaved the catalytic-site mutant precursor. Thus, RUB NS protease can function in trans.

Effects of defined mutations in the 5' nontranslated region of rubella virus genomic RNA on virus viability and macromolecule synthesis.

The 5' end of the genomic RNA of rubella virus (RUB) contains a 14-nucleotide (nt) single-stranded leader (ss-leader) followed by a stem-and-loop structure [5'(+)SL] (nt 15 to 65), the complement of which at the 3' end of the minus-strand RNA [3'(-)SL] has been proposed to function as a promoter for synthesis of genomic plus strands. A second intriguing feature of the 5' end of the RUB genomic RNA is the presence of a short (17 codons) open reading frame (ORF) located between nt 3 and 54; the ORF encoding the viral nonstructural proteins (NSPs) initiates at nt 41 in an alternate translational frame. To address the functional significance of these features, we compared the 5'-terminal sequences of six different strains of RUB, with the result that the short ORF is preserved (although the coding sequence is not conserved) as is the stem part of both the 5'(+)SL and 3'(-)SL, while the upper loop part of both structures varies. Next, using Robo302, an infectious cDNA clone of RUB, we introduced 31 different mutations into the 5'-terminal noncoding region, and their effects on virus replication and macromolecular synthesis were examined. This mutagenesis revealed that the short ORF is not essential for virus replication. The AA dinucleotide at nt 2 and 3 is of critical importance since point mutations and deletions that altered or removed both of these nucleotides were lethal. None of the other mutations within either the ss-leader or the 5'(+)SL [and accordingly within the 3'(-)SL], including deletions of up to 15 nt from the 5'(+)SL and three different multiple-point mutations that lead to destabilization of the 5'(+)SL, were lethal. Some of the mutations within both ss-leader and the 5'(+)SL resulted in viruses that grew to lower titers than the wild-type virus and formed opaque and/or small plaques; in general mutations within the stem had a more profound effect on viral phenotype than did mutations in either the ss-leader or upper loop. Mutations in the 5'(+)SL, but not in the ss-leader, resulted in a significant reduction in NSP synthesis, indicating that this structure is important for efficient translation of the NSP ORF. In contrast, viral plus-strand RNA synthesis was unaffected by the 5'(+)SL mutations as well as the ss-leader mutations, which argues against the proposed function of the 3'(-)SL as a promoter for initiation of the genomic plus-strand RNA.

Genomic sequence of the RA27/3 vaccine strain of rubella virus.

The sequence of the genome of the RA27/3 vaccine strain of rubella virus (RUB) was determined. In the process, several discrepancies between the previously reported genomic sequences of two wild RUB strains (Therien and M33) were resolved. The genomes of all three strains contain 9762 nucleotides (nts), exclusive of the 3' poly A tract. In all three strains, the genome contains (5' to 3'), a 40 nt 5' untranslated region (UTR), an open reading frame (ORF) of 6348 nts that encodes nonstructural proteins, a 123 nt UTR between the two genomic ORFs, a 3189 nt ORF that encodes the structural proteins, and a 62 nt 3' UTR. The 5' end of the subgenomic RNA was found to correspond to a uridine residue at nt 6436 of the genomic RNA. At the nucleotide level, the sequence of the three strains varied by 1.0 to 2.8%, while at the amino acid level, the sequence varied by 1.1 to 2.4% over both ORFs. The RA27/3 sequence will be of use in identification of the determinants of its attenuation, in vaccine production control and in development of second generation RUB vaccines based on recombinant DNA technology.

Improvement of the specific infectivity of the rubella virus (RUB) infectious clone: determinants of cytopathogenicity induced by RUB map to the nonstructural proteins.

A plasmid, Robo102, which contains a cDNA copy of the rubella virus (RUB) genomic RNA from which infectious transcripts can be synthesized in vitro, was recently developed (C. Y. Wang, G. Dominguez, and T. K. Frey, J. Virol. 68:3550-3557, 1994). To increase the specific infectivity of Robo102 transcripts (approximately 5 plaques/10 microg of transcripts), a modified reverse transcription-PCR method was used to amplify nearly 90% of the RUB genome in three fragments, which were then used to replace the corresponding fragments in Robo102. Replacement of a fragment covering nucleotides (nt) 5352 to 9759 of the RUB genome yielded a construct, Robo202, which produced highly infectious transcripts (10(4) plaques/microg), indicating the presence of an unrecognized deleterious mutation (or mutations) in this region of the Robo102 cDNA. Robo102 was based on the w-Therien strain of RUB, which forms opaque plaques in Vero cells, while the PCR replacement fragments were generated from a variant, f-Therien, which produces clear plaques in Vero cells. Although Robo202 contains over 4,000 nt from f-Therien, Robo202 virus produces opaque plaques. However, when the other two PCR fragments amplified from f-Therien (nt 1 to 1723 and nt 2800 to 5352) were introduced into Robo202, the resulting construct, Robo302, yielded transcripts that produced a virus that formed clear plaques. This indicates that the determinants of plaque morphology map to the regions of the genome covered by these two fragments, both of which are in the nonstructural open reading frame. Generation of Robo202/302 chimeras indicated that the most 5' terminal fragment (nt. 1 to 1723) had the greatest effect on plaque morphology. The plaque morphology was correlated with the ability of the viruses to kill infected cells. The only difference at the molecular level detected among the viruses was that the more cytopathic viruses produced more nonstructural proteins than did the less cytopathic viruses. This finding, as well as the mapping of the genetic determinants to the region of the genome encoding these proteins, indicates that the nonstructural proteins can mediate cell killing.

Neurological aspects of rubella virus infection.

Rubella virus is a single-stranded, plus-sense RNA virus belonging to the Togaviridae family. Rubella virus infection causes a benign disease known as rubella or German measles, however infection during early pregnancy can lead to severe birth defects known as congenital rubella syndrome (CRS). Sequelae of rubella virus infection include three distinct neurological syndromes: a postinfectious encephalitis following acute infection, a spectrum of neurological manifestations following congenital infection, and an extremely rare neurodegenerative disorder, progressive rubella panencephalitis (PRP), that can follow either congenital or postnatal infection. The pathogenesis of all three of these syndromes is incompletely understood. Virus invasion and replication in the brain has only been definitively demonstrated in CRS and appears to account for the majority of neurological lesions observed in this disease. Immune-mediated pathology is particularly evident in PRP and may be autoimmune in nature, possibly triggered by molecular mimicry between viral and host epitopes, considering the apparent lack of virus in the brain. The pathogenesis of rubella encephalitis following acute infection has not been determined.

Characterization of the rubella virus nonstructural protease domain and its cleavage site.

The region of the rubella virus nonstructural open reading frame that contains the papain-like cysteine protease domain and its cleavage site was expressed with a Sindbis virus vector. Cys-1151 has previously been shown to be required for the activity of the protease (L. D. Marr, C.-Y. Wang, and T. K Frey, Virology 198:586-592, 1994). Here we show that His-1272 is also necessary for protease activity, consistent with the active site of the enzyme being composed of a catalytic dyad consisting of Cys-1151 and His-1272. By means of radiochemical amino acid sequencing, the site in the polyprotein cleaved by the nonstructural protease was found to follow Gly-1300 in the sequence Gly-1299-Gly-1300-Gly-1301. Mutagenesis studies demonstrated that change of Gly-1300 to alanine or valine abrogated cleavage. In contrast, Gly-1299 and Gly-1301 could be changed to alanine with retention of cleavage, but a change to valine abrogated cleavage. Coexpression of a construct that contains a cleavage site mutation (to serve as a protease) together with a construct that contains a protease mutation (to serve as a substrate) failed to reveal trans cleavage. Coexpression of wild-type constructs with protease-mutant constructs also failed to reveal trans cleavage, even after extended in vitro incubation following lysis. These results indicate that the protease functions only in cis, at least under the conditions tested.

Pathway of rubella virus infectious entry into Vero cells.

The mechanism and the kinetics of rubella virus (RV) penetration into Vero cells were studied. By using pronase or acid treatment to inactivate virus which had adsorbed to cell membrane but had not been internalized, it was found that a period of 7 h was required in order for all of the adsorbed virus to enter the host cells. Lysosomotropic agents (monensin, methylamine, ammonium chloride and chloroquine) were used to study the mechanism by which RV penetrates host cells. Virus replication was inhibited if treatment of cells with these compounds was performed for at least 9 h after infection. However, if extracellular adsorbed virions were eliminated by acid treatment following removal of the lysosomotropic compounds, RV replication was completely inhibited by treatment with these drugs for any time period after adsorption. This indicated that the prolonged period of treatment with these compounds necessary to inhibit virus replication is due to the slow rate of RV internalization. None of the compounds had any effect on infection initiated by transfection of RV RNA, confirming that these drugs were exerting their inhibitory activity at penetration. The inhibition of RV replication by lysosomotropic compounds indicates that RV penetrates host cells by the endosomal pathway.

Double-subgenomic Sindbis virus recombinants expressing immunogenic proteins of Japanese encephalitis virus induce significant protection in mice against lethal JEV infection.

A series of double-subgenomic Sindbis virus (dsSIN) recombinants that express cassettes encoding the immunogenic proteins of Japanese encephalitis virus (JEV) [prM-E, prM-E-NS1, NS1-NS2A, 80%E (encodes the amino-terminal 80% part of E), and NS1] were constructed and analyzed for their ability to confer protective immunity in mice against lethal challenge with neurovirulent JEV. The cassettes were introduced into both 5' [second subgenomic promoter of the vector precedes the SIN structural open reading frame (SP-ORF)] and 3' (the promoter follows the SP-ORF) dsSIN vectors. The longest cassette (prM-E-NS1) was 3.2 kb in length, which is remarkable for such a small vector virus as SIN (SIN genome is roughly 11.8 kb in length). The level of expression of JEV proteins appeared similar for both 5' and 3' recombinants. In general, the stability of the recombinants obtained was found to be low (expression was lost following one to five passages at low multiplicity of infection, depending on the recombinant). However, 5' recombinants containing longer cassettes (prM-E-NS1, prM-E, NS1-NS2A) were more stable than the corresponding 3' recombinants. Intraperitoneal inoculation of mice with 10(7) PFU of dsSIN-JEV recombinants induced antibodies against JEV proteins and low titers of JEV-neutralizing antibodies were produced by mice inoculated with recombinants expressing 80%E, prM-E, and prM-E-NS1. A single immunization of mice with the dsSIN-prM-E or dsSIN-prM-E-NS1 recombinants provided 40-65% protection against peripheral lethal challenge with 10(4) LD50 of neurovirulent JEV. The results demonstrate that genetically engineered togaviruses can be successfully used as vaccine vectors.

Sindbis vectors suppress secretion of subviral particles of Japanese encephalitis virus from mammalian cells infected with SIN-JEV recombinants.

Double-subgenomic Sindbis virus (dsSIN) recombinants that express cassettes encoding prM-E or a C-terminally truncated form of E of Japanese encephalitis virus (JEV) were constructed. The products were efficiently expressed in both mammalian and mosquito cell lines infected with the dsSIN recombinants. However, suppression of prM-E secretion from mammalian cells infected with dsSIN-prM-E recombinants was observed. This suppression was more pronounced late in infection (< 5% of total product was secreted during an 8-hr chase) than early in infection (15% secretion during a 6-hr chase). In comparison, a vaccinia virus-prM-E recombinant (vP829) described previously (E. Konishi et al. (1991) Virology 185, 401-410) was shown to secrete 35-50% of total product during a 6- to 8-hr chase both early and late in infection. In contrast, secretion of prM-E from dsSIN-prM-E-infected mosquito (C6/36) cells was found to be efficient (> 50% during an 8-hr chase). The prM-E secreted from both mammalian and mosquito cells was in the form of subviral particles as determined by velocity gradient centrifugation, sensitivity to nonionic detergent, and analysis of processing of N-linked glycans. The truncated E protein expressed by the dsSIN recombinants was secreted efficiently from both mammalian and mosquito cells. Coinfection experiments with the dsSIN-JEV recombinants + wild-type vaccinia virus and vP829 + SIN demonstrated that the reduced level of secretion of subviral particles exhibited by the dsSIN-JEV recombinants was due to an inhibitory effect of the dsSIN vectors. Furthermore, this inhibitory effect was accounted for by the SIN nonstructural proteins since SIN replicons that express prM-E cassette in place of the SIN structural protein open reading frame exhibited a low level of subviral particle secretion. No self-propagating infectious particles were produced in cells transfected with SIN replicons that encode the JEV prM-E cassette. The suppression of subviral particle secretion was apparently correlated with the inhibition of cell protein synthesis which is mediated in SIN-infected vertebrate cells by expression of the SIN nonstructural proteins.