Assembly and maturation of the flavivirus Kunjin virus appear to occur in the rough endoplasmic reticulum and along the secretory pathway, respectively.

The intracellular assembly site for flaviviruses in currently not known but is presumed to be located within the lumen of the rough endoplasmic reticulum (RER). Building on previous studies involving immunofluorescence (IF) and cryoimmunoelectron microscopy of Kunjin virus (KUN)-infected cells, we sought to identify the steps involved in the assembly and maturation of KUN. Thus, using antibodies directed against envelope protein E in IF analysis, we found the accumulation of E within regions coincident with the RER and endosomal compartments. Immunogold labeling of cryosections of infected cells indicated that E and minor envelope protein prM were localized to reticulum membranes continuous with KUN-induced convoluted membranes (CM) or paracrystalline arrays (PC) and that sometimes the RER contained immunogold-labeled virus particles. Both proteins were also observed to be labeled in membranes at the periphery of the induced CM or PC structures, but the latter were very seldom labeled internally. Utilizing drugs that inhibit protein and/or membrane traffic throughout the cell, we found that the secretion of KUN particles late in infection was significantly affected in the presence of brefeldin A and that the infectivity of secreted particles was severely affected in the presence of monensin and N-nonyl-deoxynojirimycin. Nocodazole did not appear to affect maturation, suggesting that microtubules play no role in assembly or maturation processes. Subsequently, we showed that the exit of intact virions from the RER involves the transport of individual virions within individual vesicles en route to the Golgi apparatus. The results suggest that the assembly of virions occurs within the lumen of the RER and that subsequent maturation occurs via the secretory pathway.

Essential role of cyclization sequences in flavivirus RNA replication.

A possible role in RNA replication for interactions between conserved complementary (cyclization) sequences in the 5'- and 3'-terminal regions of Flavivirus RNA was previously suggested but never tested in vivo. Using the M-fold program for RNA secondary-structure predictions, we examined for the first time the base-pairing interactions between the covalently linked 5' genomic region (first ~160 nucleotides) and the 3' untranslated region (last ~115 nucleotides) for a range of mosquito-borne Flavivirus species. Base-pairing occurred as predicted for the previously proposed conserved cyclization sequences. In order to obtain experimental evidence of the predicted interactions, the putative cyclization sequences (5' or 3') in the replicon RNA of the mosquito-borne Kunjin virus were mutated either separately, to destroy base-pairing, or simultaneously, to restore the complementarity. None of the RNAs with separate mutations in only the 5' or only the 3' cyclization sequences was able to replicate after transfection into BHK cells, while replicon RNA with simultaneous compensatory mutations in both cyclization sequences was replication competent. This was detected by immunofluorescence for expression of the major nonstructural protein NS3 and by Northern blot analysis for amplification and accumulation of replicon RNA. We then used the M-fold program to analyze RNA secondary structure of the covalently linked 5'- and 3'-terminal regions of three tick-borne virus species and identified a previously undescribed additional pair of conserved complementary sequences in locations similar to those of the mosquito-borne species. They base-paired with DeltaG values of approximately -20 kcal, equivalent or greater in stability than those calculated for the originally proposed cyclization sequences. The results show that the base-pairing between 5' and 3' complementary sequences, rather than the nucleotide sequence per se, is essential for the replication of mosquito-borne Kunjin virus RNA and that more than one pair of cyclization sequences might be involved in the replication of the tick-borne Flavivirus species.

Coupling between replication and packaging of flavivirus RNA: evidence derived from the use of DNA-based full-length cDNA clones of Kunjin virus.

In order to study whether flavivirus RNA packaging is dependent on RNA replication, we generated two DNA-based Kunjin virus constructs, pKUN1 and pKUN1dGDD, allowing continuous production of replicating (wild-type) and nonreplicating (with a deletion of the NS5 gene RNA-polymerase motif GDD) full-length Kunjin virus RNAs, respectively, via nuclear transcription by cellular RNA polymerase II. As expected, transfection of pKUN1 plasmid DNA into BHK cells resulted in the recovery of secreted infectious Kunjin virions. Transfection of pKUN1dGDD DNA into BHK cells, however, did not result in the recovery of any secreted virus particles containing encapsidated dGDD RNA, despite an apparent accumulation of this RNA in cells demonstrated by Northern blot analysis and its efficient translation demonstrated by detection of correctly processed labeled structural proteins (at least prM and E) both in cells and in the culture fluid using coimmunoprecipitation analysis with anti-E antibodies. In contrast, when dGDD RNA was produced even in much smaller amounts in pKUN1dGDD DNA-transfected repBHK cells (where it was replicated via complementation), it was packaged into secreted virus particles. Thus, packaging of defective Kunjin virus RNA could occur only when it was replicated. Our results with genome-length Kunjin virus RNA and the results with poliovirus replicon RNA (C. I. Nugent et al., J. Virol. 73:427-435, 1999), both demonstrating the necessity for the RNA to be replicated before it can be packaged, strongly suggest the existence of a common mechanism for minimizing amplification and transmission of defective RNAs among the quasispecies in positive-strand RNA viruses. This mechanism may thus help alleviate the high-copy error rate of RNA-dependent RNA polymerases.

Expression and purification of enzymatically active recombinant RNA-dependent RNA polymerase (NS5) of the flavivirus Kunjin.

The NS5 protein of the flavivirus Kunjin (KUN) contains conserved sequence motifs characteristic of RNA-dependent RNA polymerase (RdRp) activity. To investigate this activity in vitro, recombinant NS5 proteins with C-terminal (NS5CHis) and N-terminal (NS5NHis) hexahistidine tags were produced in baculovirus-infected insect cells and purified to near homogeneity by nickel affinity chromatography. Purified NS5CHis exhibited RdRp activity with both specific (9 kb KUN replicon) and non-specific (8.3 kb Semliki Forest virus replicon) RNA templates; this activity did not require the presence of additional viral and/or cellular cofactors. RdRp activity of purified NS5NHis protein was reduced in comparison to NS5CHis, while purified NS5NHis incorporating a GDD-->GVD mutation within the polymerase active site (NS5GVD) lacked RdRp activity. RNase A digestion of the RdRp reaction products indicated that they were double-stranded and of a similar size to the KUN replicative form produced in Vero cells, thus demonstrating that the KUN NS5 protein has an intrinsic, albeit low and non-specific RdRp activity in vitro, similar to that reported for recombinant RdRp of other flaviviruses. However, in contrast to RNA polymerases of other Flavivirus species, purified KUN NS5 polymerase produced a single, full-length replicon RNA product, thus demonstrating efficient processivity.

Stable expression of noncytopathic Kunjin replicons simulates both ultrastructural and biochemical characteristics observed during replication of Kunjin virus.

This report focuses mainly on the characterization of a Vero cell line stably expressing the flavivirus Kunjin (KUN) replicon C20SDrep (C20SDrepVero). We showed by immunofluorescence and cryoimmunoelectron microscopy that unique flavivirus-induced membrane structures, termed convoluted membranes/paracrystalline structures, were induced in the C20SDrepVero cells. These induced cytoplasmic foci were immunolabeled with KUN virus anti-NS3 antibodies and with antibodies to the cellular markers ERGIC53 (for the intermediate compartment) and protein disulfide isomerase (for the rough endoplasmic reticulum). However, in contrast to the large perinuclear inclusions observed by immunofluorescence with anti-double-stranded (ds)RNA antibodies in KUN virus-infected cells, the dsRNA in C20SDrepVero cells was localized to small isolated foci scattered throughout the cytoplasm, which were coincident with small foci dual-labeled with the trans-Golgi specific marker GalT. Importantly, persistent expression of the KUN replicons in cells did not produce cytopathic effects, and the morphology of major host organelles (including Golgi, mitochondria, endoplasmic reticulum, and nucleus) was apparently unaffected. The amounts of plus- and minus-sense RNA synthesis in replicon cells were similar to those in KUN virus-infected cells until near the end of the latent period, but subsequently increases of about 10- and fourfold, respectively, occurred in infected cells. Virus-specified protein synthesis in C20SDrepVero cells was also about 10-fold greater than that in infected cells. When several KUN replicon cell lines were compared with respect to membrane induction, the relative efficiencies increased in parallel with increases in viral RNA and protein synthesis, consistent with the increases observed during the virus infectious cycle. Based on these observations, cell lines expressing less-efficient replicons may provide a useful tool to study early events in flavivirus RNA replication, which are difficult to assess in virus infections.

cis- and trans-acting elements in flavivirus RNA replication.

Most of the seven flavivirus nonstructural proteins (NS1 to NS5) encoded in the distal two-thirds of the RNA positive-sense genome are believed to be essential components of RNA replication complexes. To explore the functional relationships of these components in RNA replication, we used trans-complementation analysis of full-length infectious RNAs of Kunjin (KUN) virus with a range of lethal in-frame deletions in the nonstructural coding region, using as helper a repBHK cell line stably producing functional replication complexes from KUN replicon RNA. Recently we showed that replication of KUN RNAs with large carboxy-terminal deletions including the entire RNA polymerase region in the NS5 gene, representing 34 to 75% of the NS5 coding content, could be complemented after transfection into repBHK cells. In this study we have demonstrated that KUN RNAs with deletions of 84 to 97% of the NS1 gene, or of 13 to 63% of the NS3 gene including the entire helicase region, were also complemented in repBHK cells with variable efficiencies. In contrast, KUN RNAs with deletions in any of the other four nonstructural genes NS2A, NS2B, NS4A, and NS4B were not complemented. We have also demonstrated successful trans complementation of KUN RNAs containing either combined double deletions in the NS1 and NS5 genes or triple deletions in the NS1, NS3, and NS5 genes comprising as much as 38% of the entire nonstructural coding content. Based on these and our previous complementation results, we have generated a map of cis- and trans-acting elements in RNA replication for the nonstructural coding region of the flavivirus genome. These results are discussed in the context of our model on formation and composition of the flavivirus replication complex, and we suggest molecular mechanisms by which functions of some defective components of the replication complex can be complemented by their wild-type counterparts expressed from another (helper) RNA molecule.

Efficient trans-complementation of the flavivirus kunjin NS5 protein but not of the NS1 protein requires its coexpression with other components of the viral replicase.

Successful trans-complementation of the defective Kunjin virus (KUN) RNA FLdGDD with a deletion of the RNA polymerase motif GDD in the NS5 gene by using a BHK cell line, repBHK, that continuously produced a functionally active KUN replication complex (RC) from replicon RNA was recently reported (A. A. Khromykh, M. T. Kenney, and E. G. Westaway, J. Virol. 72:7270-7279, 1998). In order to identify whether this complementation of FLdGDD RNA was provided by the wild-type NS5 protein alone or with the help of other nonstructural (NS) proteins also expressed in repBHK cells, we generated BHK cell lines stably producing the individual NS5 protein (SRns5BHK) or the NS1-NS5 polyprotein (SRns1-5BHK) by using a heterologous expression vector based on a modified noncytopathic Sindbis replicon. Western blot analysis with anti-NS5 antibodies showed that the level of production of NS5 was significantly higher in SRns5BHK cells than in SRns1-5BHK cells. Despite the higher level of expressed NS5, trans-complementation of FLdGDD RNA was much less efficient in SRns5BHK cells than in SRns1-5BHK cells and produced at least 100-fold less of the secreted complemented virus. In contrast, efficient complementation of KUN RNA with lethal cysteine-to-alanine mutations in the NS1 gene was achieved both in BHK cells producing the individual KUN NS1 protein from the Sindbis replicon vector and in repBHK cells, with both cell lines expressing similar amounts of NS1 protein. These results clearly demonstrate that flavivirus NS5 coexpressed with other components of the viral replicase possesses much higher functional (trans-complementing) activity than individually expressed NS5 and that efficient trans-complementation of mutated flavivirus NS1 and NS5 proteins occurs by different mechanisms. The results are interpreted and discussed in relation to our proposed model of formation of the flavivirus RC largely based on previous ultrastructural and biochemical analyses of KUN replication.

trans-Complementation analysis of the flavivirus Kunjin ns5 gene reveals an essential role for translation of its N-terminal half in RNA replication.

Recently we described rescue of defective Kunjin virus (KUN) RNAs with small deletions in the methyltransferase and RNA polymerase motifs of the ns5 gene, using BHK cells stably expressing KUN replicon RNA (repBHK cells) as helper (A. A. Khromykh et al., J. Virol. 72:7270-7279, 1998). We have now extended our previous observations and report successful trans-complementation of defective KUN RNAs with most of the ns5 gene deleted or substituted with a heterologous (dengue virus) ns5 sequence. Replication of full-length KUN RNAs with 3'-terminal deletions of 136 (5%), 933 (34%), and 1526 (56%) nucleotides in the ns5 gene was complemented efficiently in transfected repBHK cells. RNA with a larger deletion of 2,042 nucleotides (75%) was complemented less efficiently, and RNA with an even larger deletion of 2,279 nucleotides (84%) was not complemented at all. Chimeric KUN genomic RNA containing 87% of the KUN ns5 gene replaced by the corresponding sequence of the dengue virus type 2 ns5 gene was unable to replicate in normal BHK cells but was complemented in repBHK cells. These results demonstrate for the first time complementation of flavivirus RNAs with large deletions (as much as 75%) in the RNA polymerase gene and establish that translation of most of the N-terminal half of NS5 is essential for complementation in trans. A model of formation of the flavivirus replication complex implicating a possible role in RNA replication of conserved coding sequences in the N-terminal half of NS5 is proposed based on the complementation and earlier results with KUN and on reported data with other flaviviruses.

Markers for trans-Golgi membranes and the intermediate compartment localize to induced membranes with distinct replication functions in flavivirus-infected cells.

Replication of the flavivirus Kunjin virus is associated with virus-induced membrane structures within the cytoplasm of infected cells; these membranes appear as packets of vesicles associated with the sites of viral RNA synthesis and as convoluted membranes (CM) and paracrystalline arrays (PC) containing the components of the virus-specified protease (E. G. Westaway, J. M. Mackenzie, M. T. Kenney, M. K. Jones, and A. A. Khromykh, J. Virol. 71:6650-6661, 1997). To determine the cellular origins of these membrane structures, we compared the immunolabelling patterns of several cell markers in relation to these sites by immunofluorescence and immunoelectron microscopy. A marker for the trans-Golgi membranes and the trans-Golgi network, 1,4-galactosyltransferase (GalT), was redistributed to large foci in the cytoplasm of Kunjin virus-infected cells, partially coincident with immunofluorescent foci associated with the putative sites of viral RNA synthesis. As determined by immunoelectron microscopy, the induced vesicle packets contained GalT, whereas the CM and PC contained a specific protein marker for the intermediate compartment (ERGIC53). A further indicator of the role of cellular organelles in their biogenesis was the observation that the Golgi apparatus-disrupting agent brefeldin A prevented further development of immunofluorescent foci of induced membranes if added before the end of the latent period but that once formed, these membrane foci were resistant to brefeldin A dispersion. Reticulum membranes emanating from the induced CM and PC were also labelled with the rough endoplasmic reticulum marker anti-protein disulfide isomerase and were obviously redistributed during infection. This is the first report identifying trans-Golgi membranes and the intermediate compartment as the apparent sources of the flavivirus-induced membranes involved in events of replication.

Nascent flavivirus RNA colocalized in situ with double-stranded RNA in stable replication complexes.

Incorporation of bromouridine (BrU) into viral RNA in Kunjin virus-infected Vero cells treated with actinomycin D was monitored in situ by immunofluorescence using antibodies reactive with Br-RNA. The results showed unequivocally that nascent viral RNA was located focally in the same subcellular site as dsRNA, the putative template for flavivirus RNA synthesis. When cells were labeled with BrU for 15 min, the estimated cycle period for RNA synthesis, the nascent Br-RNA was not digested in permeabilized cells by RNase A under high-salt conditions, in accord with our original model of flavivirus RNA synthesis (Chu, P. W. G., and Westaway, E. G., Virology 140, 68-79, 1985). The model assumes that there is on average only one nascent strand per template, which remains bound until displaced during the next cycle of RNA synthesis. The replicase complex located by BrU incorporation in the identified foci was stable, remaining active in incorporating BrU or [32P]orthophosphate in viral RNA after complete inhibition of protein synthesis in cycloheximide-treated cells. These results are in accord with our proposal that dsRNA detected in foci previously located by immunofluorescence or by immunogold labeling of induced vesicle packets is functioning as the true replicative intermediate (Westaway et al., J. Virol. 71, 6650-6661, 1997; Mackenzie et al., Virology 245, 203-215, 1998). Implications are that the replicase complex is able to recycle in the same membrane site in the absence of continuing protein synthesis and that possibly apart from uncleaved NS3-NS4A, it has no requirement for a polyprotein precursor late in infection.

trans-Complementation of flavivirus RNA polymerase gene NS5 by using Kunjin virus replicon-expressing BHK cells.

A BHK cell line persistently expressing a Kunjin (KUN) virus replicon RNA (repBHK, similar to our recently described ME/76Neo BHK cell line [A. A. Khromykh and E. G. Westaway, J. Virol. 71:1497-1505, 1997]) was used for rescue and propagation of KUN viruses defective in the RNA polymerase gene (NS5). A new infectious full-length KUN virus cDNA clone, FLSDX, prepared from our previously described cDNA clone pAKUN (A. A. Khromykh and E. G. Westaway, J. Virol. 68:4580-4588, 1994) and possessing approximately 10(5)-fold higher specific infectivity than that of pAKUN, was used for preparation of defective mutants. Deletions of the predicted RNA polymerase motif GDD (producing FLdGDD) and of one of the predicted methyltransferase motifs (S-adenosylmethionine [SAM] binding site, producing FLdSAM) were introduced separately into FLSDX. Transcription and transfection of FLdGDD and FLdSAM RNAs into repBHK cells but not into normal BHK cells resulted in their replication and the recovery of defective viruses able to replicate only in repBHK cells. Reverse transcription-PCR and sequencing analyses showed retention of the introduced deletions in the genomes of the recovered viruses. Retention of these deletions, as well as our inability to recover viruses able to replicate in normal BHK cells after prolonged incubation (for 7 days) of FLdGDD- or FLdSAM-transfected repBHK cells, excluded the possibility that recombination had occurred between the deleted defective NS5 genes present in transfected RNAs and the functional NS5 gene present in the repBHK cells. An RNA with a point mutation in the GDD motif (FLGVD) was also complemented in transfected repBHK cells, and defective virus was recovered by day 3 after transfection. However, in contrast to the results with FLdGDD and FLdSAM RNAs, prolonged (4 days or more) incubation of FLGVD RNA in normal BHK cells allowed recovery of a virus in which the GVD mutation had reverted via a single base change to the wild-type GDD sequence. Overall, these results represent the first demonstration of trans-complementation of defective flavivirus RNAs with deleterious deletions in the flavivirus RNA polymerase gene NS5. The complementation system described here may prove to be useful for the in vivo complementation of deletions and mutations affecting functional domains or the essential secondary structure in any of the other flavivirus nonstructural proteins.

Encapsidation of the flavivirus kunjin replicon RNA by using a complementation system providing Kunjin virus structural proteins in trans.

Kunjin virus (KUN) replicon RNA was encapsidated by a procedure involving two consecutive electroporations of BHK-21 cells, first with KUN replicon RNA C20DXrep (with prME and most of C deleted) and about 24 h later with a recombinant Semliki Forest virus (SFV) replicon RNA(s) expressing KUN structural proteins. The presence of KUN replicon RNA in encapsidated particles was demonstrated by its amplification and expression in newly infected BHK-21 cells, detected by Northern blotting with a KUN-specific probe and by immunofluorescence analysis with anti-NS3 antibodies. No infectious particles were produced when C20DXrep RNA and recombinant SFV RNAs were electroporated simultaneously. When the second electroporation was performed with a single SFV replicon RNA expressing the KUN contiguous prME genes and the KUN C gene together but under control of two separate 26S subgenomic promoters (SFV-prME-C107), a 10-fold-higher titer of infectious particles was achieved than when two different SFV replicon RNAs expressing the KUN C gene (SFV-C107) and prME genes (SFV-prME) separately were used. No SFV replicon RNAs expressing KUN structural proteins were encapsidated in secreted particles. Infectious particles pelleted by ultracentrifugation of the culture fluid from cells sequentially transfected with C20DXrep and SFV-prME-C107 RNAs were neutralized by preincubation with monoclonal antibodies to KUN E protein. Radioimmunoprecipitation analysis with anti-E antibodies of the culture fluid of the doubly transfected cells showed the presence of C, prM/M, and E proteins in the immunoprecipitated particles. Reverse transcription-PCR analysis showed that the immunoprecipitated particles also contained KUN-specific RNA. The encapsidated replicon particles sedimented more slowly than KUN virions in a 5 to 25% sucrose density gradient and were uniformly spherical, with an approximately 35-nm diameter, compared with approximately 50 nm for KUN virions. The results of this study demonstrate for the first time packaging of flavivirus RNA in trans, and they exclude a role in packaging for virtually all of the structural region. Possible applications of the developed packaging system include the definition of the packaging signal(s) in flavivirus RNA as well as the amino acid motif(s) in the structural proteins involved in RNA encapsidation, virion assembly, and secretion. Furthermore, it could facilitate the development of a noninfectious vaccine delivery system based on encapsidation of a noncytopathic flavivirus replicon expressing heterologous genes.

Subcellular localization and some biochemical properties of the flavivirus Kunjin nonstructural proteins NS2A and NS4A.

In a previous study on the replication of Kunjin virus using immunoelectron microscopy (E. G. Westaway, J. M. Mackenzie, M. T. Kenney, M. K. Jones, and A. A. Khromykh, 1997, J. Virol. 71, 6650-6661), NS1 and NS3 were found associated with double-stranded RNA (dsRNA) within vesicle packets (VP) in infected Vero cells, suggesting that these induced membrane structures may be the cytoplasmic sites of RNA replication. NS2B and NS3 (comprising the virus-encoded protease) were colocalized within distinct paracrystalline (PC) or convoluted membranes (CM), also induced in the cytoplasm, suggesting that these membranes are the sites of proteolytic cleavage. In this study we found by immunofluorescence (IF) that the small hydrophobic nonstructural proteins NS2A and NS4A were located in discrete foci in the cytoplasm of infected cells at both 16 and 24 h postinfection, partially coincident with dsRNA foci. In cryosections of infected cells at 24 h, NS2A was located by immunogold labeling primarily within VP, associated with labeled dsRNA. NS2A fused to glutathione S-transferase (GST) bound strongly to the 3' untranslated region of Kunjin RNA and also to the proposed replicase components NS3 and NS5 in cell lysates. NS4A was localized by immunogold labeling within a majority of the virus-induced membranes, including VP, CM, and PC. GST-NS4A bound weakly to the 3' untranslated region of Kunjin RNA but was bound to NS4A strongly and to most of the other viral nonstructural proteins, including NS3 and NS5. Taken together the results indicate that the flavivirus replication complex includes NS2A and NS4A in the VP in addition to the previously identified NS1 and NS3.

The replicative intermediate molecule of bovine viral diarrhoea virus contains multiple nascent strands.

The replication of bovine viral diarrhoea virus (BVDV) RNA is considered to involve replicative intermediates (RI) and replicative forms (RF) of virus RNA. These RNA species were radiolabelled metabolically by 3H-uridine in BVDV-infected cells and separated by sucrose gradient centrifugation. RNA in the fractions was then digested with RNase A in high salt (2 x SSC) and the RNase-resistance was determined. Using the Baltimore formula, this led to the calculation that the RI of BVDV contained 6-7 nascent strands on the template. This suggests that the structure of the BVDV RI is similar to that of poliovirus and dengue 2 virus.

Ultrastructure of Kunjin virus-infected cells: colocalization of NS1 and NS3 with double-stranded RNA, and of NS2B with NS3, in virus-induced membrane structures.

The subcellular location of the nonstructural proteins NS1, NS2B, and NS3 in Vero cells infected with the flavivirus Kunjin was investigated using indirect immunofluorescence and cryoimmunoelectron microscopy with monospecific antibodies. Comparisons were also made by dual immunolabelling using antibodies to double-stranded RNA (dsRNA), the putative template in the flavivirus replication complex. At 8 h postinfection, the immunofluorescent patterns showed NS1, NS2B, NS3, and dsRNA located in a perinuclear rim with extensions into the peripheral cytoplasm. By 16 h, at the end of the latent period, all patterns had changed to some discrete perinuclear foci associated with a thick cytoplasmic reticulum. By 24 h, this localization in perinuclear foci was more apparent and some foci were dual labelled with antibodies to dsRNA. In immuno-gold-labelled cryosections of infected cells at 24 h, all antibodies were associated with clusters of induced membrane structures in the perinuclear region. Two important and novel observations were made. First, one set of induced membranes comprised vesicle packets of smooth membranes dual labelled with anti-dsRNA and anti-NS1 or anti-NS3 antibodies. Second, adjacent masses of paracrystalline arrays or of convoluted smooth membranes, which appeared to be structurally related, were strongly labelled only with anti-NS2B and anti-NS3 antibodies. Paired membranes similar in appearance to the rough endoplasmic reticulum were also labelled, but less strongly, with antibodies to the three nonstructural proteins. Other paired membranes adjacent to the structures discussed above enclosed accumulated virus particles but were not labelled with any of the four antibodies. The collection of induced membranes may represent virus factories in which translation, RNA synthesis, and virus assembly occur.

Proteins C and NS4B of the flavivirus Kunjin translocate independently into the nucleus.

The subcellular locations in infected Vero cells of Kunjin (KUN) virus core protein C and NS4B were analyzed by immunofluorescence (IF) and by immunoelectron microscopy using monospecific antibodies. Selection of appropriate fixation methods for IF showed that both proteins were associated at all times with perinuclear membranes spreading outward in a reticular pattern and they entered the nucleus late during the latent period. Subsequently NS4B was also dispersed through the nucleoplasm, while C appeared in the nucleolus and the nucleoplasm. These nuclear locations were confirmed by immunogold labeling of cryosections of infected cells at 24 hr postinfection. Labeling of NS4B in cryosections was especially enriched in the perinuclear membranes of the endoplasmic reticulum. When C and NS4B were each expressed separately in stably transformed cell lines, both cytoplasmic and nuclear localization was observed by IF and confirmed by immunoelectron microscopy. Thus the two proteins translocated to the nucleus independently of each other and of other viral proteins. Dual IF with antibodies to double-stranded RNA showed that cytoplasmic locations of C and NS4B were apparently associated in part with the sites of viral RNA synthesis which were resistant to solubilization by Triton X-100.

Subgenomic replicons of the flavivirus Kunjin: construction and applications.

Several Kunjin virus (KUN) subgenomic replicons containing large deletions in the structural region (C-prM-E) and in the 3' untranslated region (3'UTR) of the genome have been constructed. Replicon RNA deltaME with 1,987 nucleotides deleted (from nucleotide 417 [in codon 108] in the C gene to nucleotide 2403 near the carboxy terminus of the E gene, inclusive) and replicon RNA C20rep with 2,247 nucleotides deleted (from nucleotide 157 [in codon 20] in C to nucleotide 2403) replicated efficiently in electroporated BHK21 cells. A further deletion from C20rep of 53 nucleotides, reducing the coding sequence in core protein to two codons (C2rep RNA), resulted in abolishment of RNA replication. Replicon deltaME/76 with a deletion of 76 nucleotides in the 3'UTR of deltaME RNA (nucleotides 10423 to 10498) replicated efficiently, whereas replicon deltaME/352 with a larger deletion of 352 nucleotides (nucleotides 10423 to 10774), including two conserved sequences RCS3 and CS3, was significantly inhibited in RNA replication. To explore the possibility of using a reporter gene assay to monitor synthesis of the positive strand and the negative strand of KUN RNA, we inserted a chloramphenicol acetyltransferase (CAT) gene into the 3'UTR of deltaME/76 RNA under control of the internal ribosomal entry site (IRES) of encephalomyelocarditis virus RNA in both plus (deltaME/76CAT[+])- and minus (deltaME/76CAT[-])-sense orientations. Although insertion of the IRES-CAT cassette in the plus-sense orientation resulted in a significant (10- to 20-fold) reduction of RNA replication compared to that of the parental deltaME/76 RNA, CAT expression was readily detected in electroporated BHK cells. No CAT expression was detected after electroporation of RNA containing the IRES-CAT cassette inserted in the minus-sense orientation despite its apparently more efficient replication (similar to that of deltaME/76 RNA); this result indicated that KUN negative-strand RNA was probably not released from its template after synthesis. Replacement of the CAT gene in the deltaME/76CAT(+) RNA with the neomycin gene (Neo) enabled selection and recovery of a BHK cell culture in which the majority of cells were continuously expressing the replicon RNA for 41 days (nine passages) without apparent cytopathic effect. The constructed KUN replicons should provide valuable tools to study flavivirus RNA replication as well as providing possible vectors for a long-lasting and noncytopathic RNA virus expression system.

Characterization of RNA synthesis during a one-step growth curve and of the replication mechanism of bovine viral diarrhoea virus.

The noncytopathic Australian bovine viral diarrhoea virus (BVDV) Trangie isolate was used to establish a one-step growth curve and to investigate previously uncharacterized aspects of pestivirus replication. The eclipse phase was found to be approximately 8 to 10 h and the first appearance of viral antigen assayed by immunofluorescence occurred around 6 h post-infection (p.i.). Both positive- and negative-sense virus RNAs were first detected at 4 h p.i. by Northern blot hybridization using strand-specific RNA probes generated by in vitro transcription from cDNA cloned from the NS3 region. The ratio of positive- to negative-sense virus RNA changed from 2:1 at 4 h p.i. to 10:1 at 12 h p.i. and thereafter. The kinetics of synthesis showed that the rate of synthesis of positive-strand viral RNA increased rapidly from 6 h p.i., whereas the rate of synthesis of the negative-strand remained constant. The copy number of genomic RNA determined by Northern blot hybridization analysis was estimated to be 1.5 x 10(4) copies per cell, 16 to 24 h p.i. Viral RNA species that were thought to represent replicative intermediate (RI) and replicative forms (RF) were detected after electrophoretic separation by urea-PAGE. Confirmation of the identity of the RI and RF was obtained using LiCl precipitation and RNase A digestion of [3H]uridine-labelled RNA. Pulse-chase labelling of BVDV-infected cells was consistent with synthesis of nascent BVDV RNA through an RI derived by strand displacement from an RF template and thus the synthesis of BVDV RNA is likely to be similar to the model proposed for flavivirus replication.

Expression and purification of the seven nonstructural proteins of the flavivirus Kunjin in the E. coli and the baculovirus expression systems.

All seven nonstructural (ns) proteins of the flavivirus Kunjin (KUN) ranging from NS1 to NS5 were expressed either alone or as fusion proteins with Glutathione-S-transferase (GST). High level expression of recombinant proteins was achieved in Spodoptera frugiperda (Sf9) cells using the baculovirus expression system in contrast to the low level of expression in E. coli. The order of the level of expression of the recombinant fusion proteins per 4 x 10(7) Sf9 cells was: GST-NS5 (yields approximately 4-5 mg) > GST-delta NS3 (approximately 1-2 mg) > GST-4A (approximately 1 mg) > GST-2B (approximately 0.5-1 mg) > GST-2A (approximately 0.5 mg) > GST-4B (approximately 0.1-0.2 mg). NS1 protein was expressed in a native form at the level of approximately 2-4 mg per 4 x 10(7) Sf9 cells. All the GST-fusion proteins were purified by adsorption on Glutathione Sepharose (GS) beads from solubilized lysates of Sf9 cells infected with the recombinant baculoviruses, or of E. coli cultures transformed with the expression plasmid and induced with IPTG. Only delta NS3 protein was recovered intact by removing GST from the fusion protein by digestion with Factor Xa protease. Attempts to cleave off the GST moiety from all the other purified recombinant proteins resulted either in inefficient cleavage or in degradation of the proteins. No GST-NS5 but from 20 to 50% of the purified GST-NS2A, GST-NS2B, GST-delta NS3, GST-NS4A, and GST-NS4B was eluted off the GS beads by adding glutathione. Thus, KUN purified recombinant proteins, either in eluted form or while immobilized on GS beads, could be used to raise monospecific antibodies, to perform functional assays or to participate in protein-protein or RNA-protein binding reactions.