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

Flavivirus Zika NS4A protein forms large oligomers in liposomes and in mild detergent

In flaviviruses such as Dengue or Zika, non-structural (NS) NS4A protein forms homo-oligomers, participates in membrane remodelling and is critical for virulence. In both viruses, mature NS4A has the same length and three predicted hydrophobic domains. The oligomers formed by Dengue NS4A are reported to be small (n = 2, 3), based on denaturing SDS gels, but no high-resolution structure of a flavivirus NS4A protein is available, and the size of the oligomer in lipid membranes is not known. Herein we show that crosslinking Zika NS4A protein in lipid membranes results in oligomers at least up to hexamers. Further, sedimentation velocity shows that NS4A in mild detergent C14-betaine appears to be in fast equilibrium between at least two species, where one is smaller, and the other larger, than a trimer or a tetramer. Consistently, sedimentation equilibrium data was best fitted to a model involving an equilibrium between dimers (n = 2) and hexamers (n = 6). Overall, the large, at least hexameric, oligomers obtained herein in liposomes and in mild detergent are more likely to represent the forms of NS4A present in cell membranes.

The cytoplasmic N-terminal tail of Zika virus NS4A protein forms oligomers in the absence of detergent or lipids

The non-structural (NS) NS4A protein in flaviviruses has three predicted transmembrane domains, is critical for virulence and participates in membrane morphogenesis. In Dengue virus (DENV), both hydrophylic N-terminal tail and its first transmembrane domain participate in the formation of oligomers which are important for pathogenicity. However, the relative importance of the N-terminal domain in oligomerization has been under debate. In particular, since in the absence of detergent or lipids, this domain (residues 1-48) in both DENV and Zika virus (ZIKV) NS4A, was found to be disordered. Recently, however, we reported preliminary data that showed that peptide ZIKV NS4A 4-58 adopts a defined secondary structure in aqueous solution and forms oligomers, signaling its importance for full length NS4A oligomerization. Herein we have performed detailed analytical ultracentrifugation experiments to further characterize the oligomerization of this peptide and also a shorter variant (residues 4-44). In both cases, sedimentation velocity produced a single species with concentration-dependent sedimentation coefficient, consistent with a fast equilibrium between at least two species. Combining sedimentation velocity and equilibrium experiments, data is best fitted to a monomer-dimer-trimer equilibrium. Possible models of NS4A oligomers obtained with AlphaFold-2 predict the stabilizing role for residues in this N-terminal domain, such as Arg20, Asn27, Ala44 and Glu50, all at highly conserved positions in flavivirus NS4A proteins. Our results are thus consistent with N-terminal domain interactions acting as one of the driving forces for NS4A homo-oligomerization.

Phosphorylation of the kinase domain regulates autophosphorylation of myosin IIIA and its translocation in microvilli

Motor activity of myosin III is regulated by autophosphorylation. To investigate the role of the kinase activity on the transporter function of myosin IIIA (Myo3A), we identified the phosphorylation sites of kinase domain (KD), which is responsible for the regulation of kinase activity and thus motor function. Using mass spectrometry, we identified six phosphorylation sites in the KD, which are highly conserved among class III myosins and Ste20-related misshapen (Msn) kinases. Two predominant sites, Thr¹⁸⁴ and Thr¹⁸⁸, in KD are important for phosphorylation of the KD as well as the motor domain, which regulates the affinity for actin. In the Caco2 cells, the full-length human Myo3A (hMyo3AFull) markedly enlarged the microvilli, although it did not show discrete localization within the microvilli. On the other hand, hMyo3AFull(T184A) and hMyo3AFull(T188A) both showed clear localization at the microvilli tips. Our results suggest that Myo3A induces large actin bundle formation to form microvilli, and phosphorylation of KD at Thr¹⁸⁴ and Thr¹⁸⁸ is critical for the kinase activity of Myo3A, and regulation of Myo3A translocation to the tip of microvilli. Retinal extracts potently dephosphorylate both KD and motor domain without IQ motifs (MDIQo), which was inhibited by okadaic acid (OA) with nanomolar range and by tautomycetin (TMC) with micromolar range. The results suggest that Myo3A phosphatase is protein phosphatase type 2A (PP2A). Supporting this result, recombinant PP2Ac potently dephosphorylates both KD and MDIQo. We propose that the phosphorylation–dephosphorylation mechanism plays an essential role in mediating the transport and actin bundle formation and stability functions of hMyo3A.

Docking studies towards exploring antiviral compounds against envelope protein of yellow fever virus

Yellow fever is among one of the most lethal viral diseases for which approved antiviral therapies were yet to be discovered. Herein, functional assignment of complete YFV proteome was done through support vector machine. Major envelope (E) protein that mediates entry of YFV into host cell was selected as a potent molecular target. Three dimensional structure of the molecular target was predicted using Modeller9v7. The model was optimized in Maestro9.0 applying OPLS AA force field and was evaluated using PROCHECK, ProSA, ProQ and Profile 3D. The BOG pocket residues Val48, Glu197, Thr200, Ile204, Thr265, Thr268 and Gly278 were located in YFV E protein using SiteMap2.3. More than one million compounds of Ligandinfo Meta database were explored using a computational virtual screening protocol targeting BOG pocket of the E protein. Finally, ten top ranked lead molecules with strong binding affinity to BOG pocket of YFV E protein were identified based on XP Gscore. Drug likeliness and comparative bioactivity analysis for these leads using QikProp3.2 had shown that these molecules would have the potential to act as better drug. Thus, the 10 lead molecules suggested in the present study would be of interest as promising starting point for designing antiviral compound against yellow fever.

Functional assignment to JEV proteins using SVM

Identification of different protein functions facilitates a mechanistic understanding of Japanese encephalitis virus (JEV) infection and opens novel means for drug development. Support vector machines (SVM), useful for predicting the functional class of distantly related proteins, is employed to ascribe a possible functional class to Japanese encephalitis virus protein. Our study from SVMProt and available JE virus sequences suggests that structural and nonstructural proteins of JEV genome possibly belong to diverse protein functions, are expected to occur in the life cycle of JE virus. Protein functions common to both structural and non-structural proteins are iron-binding, metal-binding, lipid-binding, copper-binding, transmembrane, outer membrane, channels/Pores - Pore-forming toxins (proteins and peptides) group of proteins. Non-structural proteins perform functions like actin binding, zinc-binding, calcium-binding, hydrolases, Carbon-Oxygen Lyases, P-type ATPase, proteins belonging to major facilitator family (MFS), secreting main terminal branch (MTB) family, phosphotransfer-driven group translocators and ATP-binding cassette (ABC) family group of proteins. Whereas structural proteins besides belonging to same structural group of proteins (capsid, structural, envelope), they also perform functions like nuclear receptor, antibiotic resistance, RNA-binding, DNA-binding, magnesium-binding, isomerase (intra-molecular), oxidoreductase and participate in type II (general) secretory pathway (IISP).

West Nile virus strain Kunjin NS5 polymerase is a phosphoprotein localized at the cytoplasmic site of viral RNA synthesis

Using West Nile virus strain Kunjin virus (WNV(KUN)) as a model system for flavivirus replication, we showed that the virus replication complex (RC) is associated with the dsRNA template located in induced membranes only in the cytoplasm. In this report we established for the first time that the RNA-dependent RNA polymerase NS5 is located in flavivirus-induced membranes, including the site of viral RNA replication. We found no evidence for nuclear localization of the essential RC components NS5 and its dsRNA template for WNV(KUN) or the closely related WNV strain Sarafend, by immuno-electron microscopy or by immunofluorescence. Metabolic radiolabelling with [(32)P]orthophosphate revealed that WNV(KUN) NS5 was phosphorylated and this was confirmed by Western blotting with antibodies specific for phosphorylated serine and threonine only. These observations of a cytoplasmic location for the WNV polymerase and its phosphorylation state correspond to the characteristics of the hepatitis C virus RNA polymerase NS5B.

Antibodies against West Nile Virus nonstructural protein NS1 prevent lethal infection through Fc gamma receptor-dependent and -independent mechanisms

The flavivirus nonstructural protein NS1 is a highly conserved secreted glycoprotein that does not package with the virion. Immunization with NS1 elicits a protective immune response against yellow fever, dengue, and tick-borne encephalitis flaviviruses through poorly defined mechanisms. In this study, we purified a recombinant, secreted form of West Nile virus (WNV) NS1 glycoprotein from baculovirus-infected insect cells and generated 22 new NS1-specific monoclonal antibodies (MAbs). By performing competitive binding assays and expressing truncated NS1 proteins on the surface of yeast (Saccharomyces cerevisiae) and in bacteria, we mapped 21 of the newly generated MAbs to three NS1 fragments. Prophylaxis of C57BL/6 mice with any of four MAbs (10NS1, 14NS1, 16NS1, and 17NS1) strongly protected against lethal WNV infection (75 to 95% survival, respectively) compared to saline-treated controls (17% survival). In contrast, other anti-NS1 MAbs of the same isotype provided no significant protection. Notably, 14NS1 and 16NS1 also demonstrated marked efficacy as postexposure therapy, even when administered as a single dose 4 days after infection. Virologic analysis showed that 17NS1 protects at an early stage in infection through a C1q-independent and Fc gamma receptor-dependent pathway. Interestingly, 14NS1, which maps to a distinct region on NS1, protected through a C1q- and Fc gamma receptor-independent mechanism. Overall, our data suggest that distinct regions of NS1 can elicit protective humoral immunity against WNV through different mechanisms.

NS1 protein secretion during the acute phase of West Nile virus infection

The West Nile virus (WNV) nonstructural protein NS1 is a protein of unknown function that is found within, associated with, and secreted from infected cells. We systematically investigated the kinetics of NS1 secretion in vitro and in vivo to determine the potential use of this protein as a diagnostic marker and to analyze NS1 secretion in relation to the infection cycle. A sensitive antigen capture enzyme-linked immunosorbent assay (ELISA) for detection of WNV NS1 (polyclonal-ACE) was developed, as well as a capture ELISA for the specific detection of NS1 multimers (4G4-ACE). The 4G4-ACE detected native NS1 antigens at high sensitivity, whereas the polyclonal-ACE had a higher specificity for recombinant forms of the protein. Applying these assays we found that only a small fraction of intracellular NS1 is secreted and that secretion of NS1 in tissue culture is delayed compared to the release of virus particles. In experimentally infected hamsters, NS1 was detected in the serum between days 3 and 8 postinfection, peaking on day 5, the day prior to the onset of clinical disease; immunoglobulin M (IgM) antibodies were detected at low levels on day 5 postinfection. Although real-time PCR gave the earliest indication of infection (day 1), the diagnostic performance of the 4G4-ACE was comparable to that of real-time PCR during the time period when NS1 was secreted. Moreover, the 4G4-ACE was found to be superior in performance to both the IgM and plaque assays during this time period, suggesting that NS1 is a viable early diagnostic marker of WNV infection.

Comparisons of physical separation methods of Kunjin virus-induced membranes

The two sets of connected membranes induced in Kunjin virus-infected cells are characterized by the presence of NS3 helicase/protease in both, and by RNA-dependent RNA polymerase (RdRp) activity plus the associated double-stranded RNA (dsRNA) template in vesicle packets (VP), or by the absence of both the VP-specific markers in the convoluted membranes/paracrystalline arrays (CM/PC). Attempts were made to separate flavivirus-induced membranes by sedimentation or flotation analyses in density gradients of sucrose or iodixanol, respectively, after treatment of cell lysates by sonication, osmotic shock, or tryptic digestion. Only osmotic shock treatment provided suggestive evidence of separation. This was explored by flow cytometry analysis (FCA) of RdRp active membrane fractions from a sucrose gradient, using dual fluorescent labelling via antibodies to NS3 and dsRNA. FCA revealed the presence of a dual labelled membrane population indicative of VP, and in a faster sedimenting fraction a membrane population able to be labelled only in NS3, representative of CM/PC and associated (R)ER. It was postulated that osmotic shock ruptured the bounding membrane of the VP, releasing the enclosed small vesicles associated with the Kunjin virus replication complex characterized previously. Notably, the presence of the full spectrum of nonstructural proteins in some membrane fractions was not a reliable marker for RdRp activity. These experiments may provide the opportunity for isolation of relatively pure flavivirus replication complexes in their native membrane-associated state by fluorescence-activated cell sorting.

Diagnostic immunoassays for tick-borne encephalitis virus based on recombinant baculovirus protein expression

The baculovirus expression system that utilizes Autographa californica nuclear polyhedrosis virus was used to express the highly antigenic envelope protein E of a tick-borne encephalitis (TBE) complex virus, as well as a C-terminally truncated form of protein E (Etr). The recombinant proteins were produced with a histidine-tag at their carboxy-terminus. Protein purification by nickel agarose chromatography resulted in high concentrations of pure Etr protein, but only poor yields of E protein. Therefore, Etr was used to develop a sensitive and specific enzyme-linked immunosorbent assay (ELISA), as well as an immunoblot assay to detect TBE virus-specific antibodies in sera from immunized human blood donors. Sera from non-vaccinated blood donors were used as controls. The data show that the recombinant TBE virus-specific Etr protein exhibits the antigenic epitopes and conformation necessary for specific antigen-antibody recognition. Thus, the baculovirus expression system provides a cheap and easy method to generate recombinant viral antigens for TBE virus-specific serodiagnosis.

Identification and characterization of a novel protein inhibitor of type 1 protein phosphatase

We have isolated human cDNA for a novel type 1 protein phosphatase (PP1) inhibitory protein, named inhibitor-4 (I-4), from a cDNA library of germ cell tumors. I-4, composed of 202 amino acids, is 44% identical to a PP1 inhibitor, inhibitor-2 (I-2). I-4 conserves functionally important structure of I-2 and exhibited similar biochemical properties. I-4 inhibited activity of the catalytic subunit of PP1 (PP1C), specifically with an IC(50) of 0.2 nM, more potently than I-2 with an IC(50) of 2 nM. I-4 weakly inhibited the activity of myosin-associated phosphates (PP1M). However, the level of inhibition of PP1M was increased during preincubation of PP1M with I-4, suggesting that the inhibition is caused by interaction of I-4 with PP1C in such a manner that it competes with the M subunit of PP1M. Gel overlay experiments showed that I-4 binds PP1C directly. Three I-4 peptides containing the N-terminal residues 1-123, 1-131, and 1-142 all showed strong binding ability to PP1C but did not show PP1 inhibitory activity, whereas an I-2 peptide (residues 1-134), lacking the corresponding C-terminal residues, potently inhibited PP1C activity as previously reported. Removal of the 18 N-terminal amino acid residues from I-4 dramatically reduced the PP1 binding activity with a correlated loss of inhibitory activity, whereas removal of the 10 N-terminal residues had only a little effect. The two peptides GST-I-4(19-131) and GST-I-4(132-202) showed ability to bind to PP1C, albeit very weakly. These results strongly suggest a multiple-point interaction between I-4 and PP1C, which is thought to cause the inhibition of I-4 which is stronger than the inhibition of I-2.

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.

Identification and analysis of truncated and elongated species of the flavivirus NS1 protein

The flavivirus non-structural glycoprotein NS1 is often detected in Western blots as a heterogeneous cluster of bands due to glycosylation variations, precursor-product relationships and/or alternative cleavage sites in the viral polyprotein. In this study, we determined the basis of structural heterogeneity of the NS1 protein of Murray Valley encephalitis virus (MVE) by glycosylation analysis, pulse-chase experiments and terminal amino acid sequencing. Inhibition of N-linked glycosylation by tunicamycin revealed that NS1 synthesised in MVE-infected C6/36 cells was derived from two polypeptide backbones of 39 kDa (NS1(o)) and 47 kDa (NS1'). Pulse-chase experiments established that no precursor-product relationship existed between NS1(o) and NS1' and that both were stable end products. Terminal sequencing revealed that the N- and C-termini of NS1(o) were located at amino acid positions 714 and 1145 in the polyprotein respectively, consistent with the predicted sites based upon sequence homology with other flaviviruses. Expression of the NS1 gene alone or in conjunction with NS2A by recombinant baculoviruses demonstrated that the production of NS1' was dependent on the presence of NS2A, indicating that the C-terminus of the larger protein was generated within NS2A. A smaller form (31 kDa) of NS1 (deltaNS1) was also identified in MVE-infected Vero cultures, and amino acid sequencing revealed a 120-residue truncation at the N-terminus of this protein. This corresponds closely with the in-frame 121-codon deletion at the 5' end of the NS1 gene of defective MVE viral RNA (described by Lancaster et al. in 1998), suggesting that deltaNS1 may be a translation product of defective viral RNA.

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.

Expression of Coxsackievirus B4 proteins VP0 and 2C in Escherichia coli and generation of virus protein recognizing antisera

Coxsackievirus B4 (CBV-4) capsid protein VP0 and non-structural 2C protein were expressed and purified using a glutathione-S-transferase (GST) fusion protein expression system. We used a full-size CBV-4 cDNA as a template to amplify the genes by polymerase chain reaction (PCR). The genes were cloned into expression vector pGEX-2T and expressed as a fusion protein with GST. The GST-fusion proteins (GST-2C and GST-VP0) were purified in denatured and native forms and used to generate antibodies in rabbits. The antisera raised against GST-VP0 fusion protein recognized the corresponding structural proteins (VP0, VP2 and VP4) from purified CBV-4 preparations and infected cell lysates. In addition, cross-reactivity with CAV-9 and CBV-5 capsid proteins was observed. Anti-GST-2C antisera precipitated viral 2C protein in CBV-4-infected GMK cells, showing that the antibodies recognize the corresponding natural antigen.

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.