Selection and analysis of mutations in an encephalomyocarditis virus internal ribosome entry site that improve the efficiency of a bicistronic flavivirus construct

Flaviviruses have a positive-stranded RNA genome, which simultaneously serves as an mRNA for translation of the viral proteins. All of the structural and nonstructural proteins are translated from a cap-dependent cistron as a single polyprotein precursor. In an earlier study (K. K. Orlinger, V. M. Hoenninger, R. M. Kofler, and C. W. Mandl, J. Virol. 80:12197-12208, 2006), it was demonstrated that an artificial bicistronic flavivirus genome, TBEV-bc, in which the region coding for the viral surface glycoproteins prM and E from tick-borne encephalitis virus (TBEV) had been removed from its natural context and inserted into the 3' noncoding region under the control of an internal ribosome entry site (IRES) from encephalomyocarditis virus (EMCV) produces viable, infectious virus when cells are transfected with this RNA. The rates of RNA replication and infectious particle formation were significantly lower with TBEV-bc, however, than with wild-type TBEV. In this study, we have identified two types of mutations, selected by passage in BHK-21 cells, that enhance the growth properties of TBEV-bc. The first type occurred in the E protein, and these most likely increase the affinity of the virus for heparan sulfate on the cell surface. The second type occurred in the inserted EMCV IRES, in the oligo(A) loop of the J-K stem-loop structure, a binding site for the eukaryotic translation initiation factor 4G. These included single-nucleotide substitutions as well as insertions of additional adenines in this loop. An A-to-C substitution in the oligo(A) loop decreased the efficiency of the IRES itself but nevertheless resulted in improved rates of virus particle formation and overall replication efficiency. These results demonstrate the need for proper balance in the competition for free template RNA between the viral RNA replication machinery and the cellular translation machinery at the two different start sites and also identify specific target sites for the improvement of bicistronic flavivirus expression vectors.

Probing the flavivirus membrane fusion mechanism by using monoclonal antibodies

In this study, we investigated in a flavivirus model (tick-borne encephalitis virus) the mechanisms of fusion inhibition by monoclonal antibodies directed to the different domains of the fusion protein (E) and to different sites within each of the domains by using in vitro fusion assays. Our data indicate that, depending on the location of their binding sites, the monoclonal antibodies impaired early or late stages of the fusion process, by blocking the initial interaction with the target membrane or by interfering with the proper formation of the postfusion structure of E, respectively. These data provide new insights into the mechanisms of flavivirus fusion inhibition by antibodies and their possible contribution to virus neutralization.

Dynamics of antigenic and genetic changes in the hemagglutinins of influenza A/H3N2 viruses of three consecutive seasons (2002/2003 to 2004/2005) in Austria

Human influenza viruses are subject to continuous antigenic drift and this phenomenon poses great problems for the annual production of vaccines which should ideally be manufactured from strains closely matching the predominant strains of the coming influenza season. We have investigated the dynamics of antigenic and genetic changes in the hemagglutinins of circulating influenza A/H3N2 strains in three consecutive seasons (2002/2003 to 2004/2005) in Austria by sequence analysis of the HA1 domain and by antigenic characterization using a hemagglutination inhibition assay. Each of the three seasons was dominated by a single and different H3N2 variant, but in all cases sequencing revealed the co-circulation of a drift variant which would have been missed by conventional antigenic analysis. These emerging strains always showed already a close genetic relationship to the dominating strain of the following season. Our results underscore the value of monitoring seasonal influenza strain dynamics by sequence analysis as an instrument that can provide important and timely information on the appearance of strains with epidemiologic significance.

Characterization of a structural intermediate of flavivirus membrane fusion

Viral membrane fusion proceeds through a sequence of steps that are driven by triggered conformational changes of viral envelope glycoproteins, so-called fusion proteins. Although high-resolution structural snapshots of viral fusion proteins in their prefusion and postfusion conformations are available, it has been difficult to define intermediate structures of the fusion pathway because of their transient nature. Flaviviruses possess a class II viral fusion protein (E) mediating fusion at acidic pH that is converted from a dimer to a trimer with a hairpin-like structure during the fusion process. Here we show for tick-borne encephalitis virus that exposure of virions to alkaline instead of acidic pH traps the particles in an intermediate conformation in which the E dimers dissociate and interact with target membranes via the fusion peptide without proceeding to the merger of the membranes. Further treatment to low pH, however, leads to fusion, suggesting that these monomers correspond to an as-yet-elusive intermediate required to convert the prefusion dimer into the postfusion trimer. Thus, the use of nonphysiological conditions allows a dissection of the flavivirus fusion process and the identification of two separate steps, in which membrane insertion of multiple copies of E monomers precedes the formation of hairpin-like trimers. This sequence of events provides important new insights for understanding the dynamic process of viral membrane fusion.

The fusion of cellular lipid membranes is an essential process in all forms of life. Such membranes are also part of a specific structural class of viruses—so-called enveloped viruses—that include influenza virus, HIV, severe acute respiratory syndrome coronavirus, Ebola virus, yellow fever virus, and many others. The fusion of the viral with a cellular membrane is a key step in the life cycle of these viruses and allows the delivery of their genetic information into cells. This entry step is controlled by specific proteins at the viral surface that are primed to undergo dramatic structural changes and thus drive membrane fusion. An interference with this process can be a powerful means for inhibiting virus replication and fusion inhibitors have recently become a valuable addition to the armamentarium of anti-HIV treatments. In the present study, we identified an intermediate of the fusion pathway of flaviviruses, which comprise mosquito- and tick-transmitted viruses such as yellow fever, dengue, West Nile, Japanese encephalitis, and tick-borne encephalitis viruses. This work has generated further insights into the mechanism of flavivirus membrane fusion and can thus provide new leads for the development of antiviral agents against these important human pathogens.

Cryptic properties of a cluster of dominant flavivirus cross-reactive antigenic sites

A number of flaviviruses are important human pathogens, including yellow fever, dengue, West Nile, Japanese encephalitis, and tick-borne encephalitis (TBE) viruses. Infection with or immunization against any of these viruses induces a subset of antibodies that are broadly flavivirus cross-reactive but do not exhibit significant cross-neutralization. Nevertheless, these antibodies can efficiently bind to the major envelope protein (E), which is the main target of neutralizing and protective antibodies because of its receptor-binding and membrane fusion functions. The structural basis for this phenomenon is still unclear. In our studies with TBE virus, we have provided evidence that such cross-reactive antibodies are specific for a cluster of epitopes that are partially occluded in the cage-like assembly of E proteins at the surfaces of infectious virions and involve-but are not restricted to-amino acids of the highly conserved internal fusion peptide loop. Virus disintegration leads to increased accessibility of these epitopes, allowing the cross-reactive antibodies to bind with strongly increased avidity. The cryptic properties of these sites in the context of infectious virions can thus provide an explanation for the observed lack of efficient neutralizing activity of broadly cross-reactive antibodies, despite their specificity for a functionally important structural element in the E protein.

Flavivirus membrane fusion

Flavivirus membrane fusion is mediated by a class II viral fusion protein, the major envelope protein E, and the fusion process is extremely fast and efficient. Understanding of the underlying mechanisms has been advanced significantly by the determination of E protein structures in their pre- and post-fusion conformations and by the elucidation of the quarternary organization of E proteins in the viral envelope. In this review, these structural data are discussed in the context of functional and biochemical analyses of the flavivirus fusion mechanism and its characteristics are compared with those of other class II- and class I-driven fusion processes.

Serological evidence for tick-borne encephalitis, borreliosis, and human granulocytic anaplasmosis in Mongolia

Five hundred and forty-five serum samples from donors from various parts of Mongolia were investigated for antibodies against the tick-borne encephalitis (TBE) virus, Borrelia burgdorferi, and Anaplasma phagocytophilum. Seroprevalence against TBE was 5.1% in the province of Selenge and 0.9% in Bulgan province, seroprevalence against B. burgdorferi was 1.9% in Selenge province and Bulgan province, 13.9% in Dornogov province, and 3.0% in Tov province and Ulaanbaatar. Seroprevalence against A. phagocytophilum was 2.3% in Selenge province, 5.6% in Bulgan province, 2.8% in Dornogov province, and 3.0% in Tov province and Ulaanbaatar. We conclude that all three pathogens are endemic in Mongolia.

Entry functions and antigenic structure of flavivirus envelope proteins

The envelope proteins (E) of flaviviruses form an icosahedral cage-like structure of homodimers that cover completely the surface of mature virions and are responsible for receptor-binding and membrane fusion. Fusion is triggered by the acidic pH in endosomes which induces dramatic conformational changes of E that drive the merger of the membranes. We have identified an alternative trigger that induces the first phase of the fusion process only, but then leads to an arrest at an intermediate stage. These data suggest that the early and late stages of flavivirus fusion are differentially controlled by intersubunit and intrasubunit constraints of the fusion protein, respectively. Details of the molecular antigenic structure of the flavivirus E protein were revealed by the use of neutralization escape mutants as well as recombinant expression systems for the generation of virus-like particles. The experimental data provide evidence that each of the three domains contributing to the external face of the E protein can induce and bind neutralizing antibodies. Broadly flavivirus cross-reactive antibodies, however, primarily recognize a site involving residues of the highly conserved fusion peptide loop which is cryptic and largely inaccessible on the surface of native infectious virions.

Differences in the postfusion conformations of full-length and truncated class II fusion protein E of tick-borne encephalitis virus

The trimeric postfusion structure of the C-terminally truncated fusion protein E of the flavivirus tick-borne encephalitis virus, a class II viral fusion protein, was previously determined (S. Bressanelli, K. Stiasny, S. L. Allison, E. A. Stura, S. Duquerroy, J. Lescar, F. X. Heinz, and F. A. Rey, EMBO J. 23:728-738, 2004). In this study we compared the properties of this truncated form with the full-length trimer and found that the so-called stem-anchor region not only confers additional stability to the full-length molecule but also structurally modifies the protein domain carrying the fusion peptide loop. These data provide experimental evidence to support the model of a fusion process that leads to the interaction of the stem-anchor region with the fusion peptide loop in the postfusion trimer.

Heterologous gene expression by infectious and replicon vectors derived from tick-borne encephalitis virus and direct comparison of this flavivirus system with an alphavirus replicon

The flavivirus tick-borne encephaltis virus (TBEV) was established as a vector system for heterologous gene expression. The variable region of the genomic 3′ non-coding region was replaced by an expression cassette consisting of the reporter gene enhanced green fluorescent protein (EGFP) under the translational control of an internal ribosomal entry site element, both in the context of an infectious virus genome and of a replicon lacking the genes of the surface proteins prM/M and E. The expression level and the stability of expression were measured by fluorescence-activated cell-sorting analysis and compared to an established alphavirus replicon vector derived from Venezuelan equine encephaltis virus (VEEV), expressing EGFP under the control of its natural subgenomic promoter. On the first day, the alphavirus replicon exhibited an approximately 180-fold higher expression level than the flavivirus replicon, but this difference decreased to about 20- and 10-fold on days 2 and 3, respectively. Four to six days post-transfection, foreign gene expression by the VEEV replicon vanished almost completely, due to extensive cell killing. In contrast, in the case of the TBEV replicon, the percentage of positive cells and the amount of EGFP expression exhibited only a moderate decline over a time period of almost 4 weeks. The infectious TBEV vector expressed less EGFP than the TBEV replicon at all times. Significant expression from the infectious vector was maintained for four cell-culture passages. The results indicate that the VEEV vector is superior with respect to achieving high expression levels, but the TBEV system may be advantageous for applications that require a moderate, but more enduring, gene expression.

Dengue virus: molecular basis of cell entry and pathogenesis, 25-27 June 2003, Vienna, Austria

Multivalent dengue vaccines now in late stage development pose unique vaccine safety challenges in that primary or secondary vaccine failures might place vaccines at risk to antibody-dependent enhanced (ADE) wild-type dengue infections. This conference was organized to address this unique vaccine safety issue. New data were presented on the structure of dengue and other flaviviruses, the cellular receptors of dengue virus for biologically relevant cells, dengue viral cell entry mechanisms and mechanisms underlying in vivo protection, neutralization and enhancement of dengue virus infection. It was concluded that a targeted research program should aim to develop an in vitro test to characterize persons immunized with dengue vaccines as completely or partially protected. Achievement of this aim will require a better understanding of the basic mechanisms by which dengue viruses recognize, attach, enter and infect relevant human cells and how antibodies protect against dengue infections.

Tick-borne virus diseases of human interest in Europe

Several human diseases in Europe are caused by viruses transmitted by tick bite. These viruses belong to the genus Flavivirus, and include tick-borne encephalitis virus, Omsk haemorrhagic fever virus, louping ill virus, Powassan virus, Nairovirus (Crimean-Congo haemorrhagic fever virus) and Coltivirus (Eyach virus). All of these viruses cause more or less severe neurological diseases, and some are also responsible for haemorrhagic fever. The epidemiology, clinical picture and methods for diagnosis are detailed in this review. Most of these viral pathogens are classified as Biosafety Level 3 or 4 agents, and therefore some of them have been classified in Categories A-C of potential bioterrorism agents by the Centers for Disease Control and Prevention. Their ability to cause severe disease in man means that these viruses, as well as any clinical samples suspected of containing them, must be handled with specific and stringent precautions.

Tick-borne encephalitis in childhood--consensus 2004

Tick-borne encephalitis (TBE) is a communicable disease caused by a flavi-virus, ticks being the main vectors. The nervous system is affected, four clinical features of different severity are observed: meningitis, meningoencephalitis, meningoencephalomyelitis, meningoradiculoneuritis. TBE is a preventable disease, which is rapidly becoming a growing public health problem in Europe. So far no causal treatment is possible but an efficient, safe vaccination is available. During the 6th meeting of the International Scientific Working Group on TBE with the main conference issue "Tick-borne encephalitis in childhood" an international consensus was achieved. In countries where TBE is endemic--and not prevented by immunization--both children and adults are affected. The disease in children is generally milder, although severe illness may occur and even lead to permanent impairment of the quality of life due to neuropsychological sequelae. Therefore immunization should be offered to all children living in or traveling to endemic areas.

Isolation of capsid protein dimers from the tick-borne encephalitis flavivirus and in vitro assembly of capsid-like particles

Flaviviruses have a spherical capsid that is composed of multiple copies of a single capsid protein and, in contrast to the viral envelope, apparently does not have an icosahedral structure. So far, attempts to isolate distinct particulate capsids and soluble forms of the capsid protein from purified virions as well as to assemble capsid-like particles in vitro have been largely unsuccessful. Here we describe the isolation of nucleocapsids from tick-borne encephalitis (TBE) virus and their disintegration into a capsid protein dimer by high-salt treatment. Purified capsid protein dimers could be assembled in vitro into capsid-like particles when combined with in vitro transcribed viral RNA. Particulate structures could also be obtained when single-stranded DNA oligonucleotides were used. These data suggest that the dimeric capsid protein functions as a basic building block in the assembly process of flaviviruses.

Effect of membrane curvature-modifying lipids on membrane fusion by tick-borne encephalitis virus

Enveloped viruses enter cells by fusion of their own membrane with a cellular membrane. Incorporation of inverted-cone-shaped lipids such as lysophosphatidylcholine (LPC) into the outer leaflet of target membranes has been shown previously to impair fusion mediated by class I viral fusion proteins, e.g., the influenza virus hemagglutinin. It has been suggested that these results provide evidence for the stalk-pore model of fusion, which involves a hemifusion intermediate (stalk) with highly bent outer membrane leaflets. Here, we investigated the effect of inverted-cone-shaped LPCs and the cone-shaped oleic acid (OA) on the membrane fusion activity of a virus with a class II fusion protein, the flavivirus tick-borne encephalitis virus (TBEV). This study included an analysis of lipid mixing, as well as of the steps preceding or accompanying fusion, i.e., binding to the target membrane and lipid-induced conformational changes in the fusion protein E. We show that the presence of LPC in the outer leaflet of target liposomes strongly inhibited TBEV-mediated fusion, whereas OA caused a very slight enhancement, consistent with a fusion mechanism involving a lipid stalk. However, LPC also impaired the low-pH-induced binding of a soluble form of the E protein to liposomes and its conversion into a trimeric postfusion structure that requires membrane binding at low pH. Because inhibition is already observed before the lipid-mixing step, it cannot be determined whether impairment of stalk formation is a contributing factor in the inhibition of fusion by LPC. These data emphasize, however, the importance of the composition of the target membrane in its interactions with the fusion peptide that are crucial for the initiation of fusion.

A novel principle of attenuation for the development of new generation live flavivirus vaccines

The genus Flavivirus includes a number of important human pathogens that impose major health problems in large regions of the world. The emergence of flaviviruses in new geographic regions (e.g., West Nile virus in North America) and rapid socioeconomic changed in many developing countries where flaviviruses such as dengue virus and Japanese encephalitis virus and endemic demand the development of new vaccines against these diseases. Using tick-borne encephalitis virus as a model we have established a new method to generate attenuated flavivirus strains that may be useful for generating cost-effective and safe live vaccines. This method relies on the specific introduction of deletions into one of the structural proteins, the capsid protein C. These deletions remove parts or all of an internal stretch of hydrophobic amino acid residues that probably is involved in virion assembly. We observed that remarkably long deletions were tolerated, yielding viable viral mutants that were highly attenuated in the mouse model but efficiently induced protective immunity. Biochemical analyses suggested that attenuation was caused by an assembly defect of infectious virions but the mutants produced ample amounts of non-infections subviral particles. The generation of viable mutants with deletions longer that 16 amino acid residues depended on additional, spontaneously emerging mutations within protein C that increased the hydrophobicity of the mutant protein. Although the second-site mutations increased infectivity, they did not restore neuroinvasiveness. Mouse experiments demonstrated excellent safety and immunogenicity profiles for these mutants.

Characterization of a membrane-associated trimeric low-pH-induced Form of the class II viral fusion protein E from tick-borne encephalitis virus and its crystallization

The interaction of a dimeric membrane anchor-free form of the envelope protein E (sE dimer) from tick-borne encephalitis virus with liposomes at acidic pH levels leads to its conversion into membrane-inserted sE trimers. Electron microscopy shows that these trimers have their long dimensions along the threefold molecular axis, which is oriented perpendicularly to the plane of the membrane, where the protein inserts via the internal fusion peptide. Liposomes containing sE at their surface display paracrystalline arrays of protein in a closely packing arrangement in which each trimer is surrounded by six others, suggesting cooperativity in the insertion process. sE trimers, solubilized with nonionic detergents, yielded three-dimensional crystals suitable for X-ray diffraction analysis.

Structure of a flavivirus envelope glycoprotein in its low-pH-induced membrane fusion conformation

Enveloped viruses enter cells via a membrane fusion reaction driven by conformational changes of specific viral envelope proteins. We report here the structure of the ectodomain of the tick-borne encephalitis virus envelope glycoprotein, E, a prototypical class II fusion protein, in its trimeric low-pH-induced conformation. We show that, in the conformational transition, the three domains of the neutral-pH form are maintained but their relative orientation is altered. Similar to the postfusion class I proteins, the subunits rearrange such that the fusion peptide loops cluster at one end of an elongated molecule and the C-terminal segments, connecting to the viral transmembrane region, run along the sides of the trimer pointing toward the fusion peptide loops. Comparison with the low-pH-induced form of the alphavirus class II fusion protein reveals striking differences at the end of the molecule bearing the fusion peptides, suggesting an important conformational effect of the missing membrane connecting segment.

Mimicking live flavivirus immunization with a noninfectious RNA vaccine

Flaviviruses are human pathogens of world-wide medical importance. They have recently received much additional attention because of their spread to new regions (such as West Nile virus to North America), highlighting their potential as newly emerging disease agents. Using tick-borne encephalitis virus, we have developed and evaluated in mice a new genetic vaccine based on self-replicating but noninfectious RNA. This RNA contains all of the necessary genetic information for establishing its replication machinery in the host cell, thus mimicking a natural infection. However, genetic modifications in the region encoding the capsid protein simultaneously prevent the assembly of infectious virus particles and promote the secretion of noninfectious subviral particles that elicit neutralizing antibodies. These characteristics demonstrate that a new generation of flavivirus vaccines can be designed that stimulate the same spectrum of innate and specific immune responses as a live vaccine but have the safety features of an inactivated vaccine.

Tick-borne encephalitis and the impact of vaccination

TBE virus is endemic in many parts of Europe and Northern Asia, and in these regions it causes more than 10,000 severe cases of central nervous system disease in humans each year. The virus is primarily transmitted to humans when infected ticks take a blood meal, but infections due to the consumption of unpasteurized milk, primarily from goats, occur in certain regions. Based on genetic analyses, three closely related subtypes can be distinguished and are designated European, Siberian, and Far Eastern subtype according to their primary geographic distribution. Consistent with their close antigenic relationships, immunization studies in animals have revealed a high degree of cross-protection between virus strains belonging to different subtypes. The commercially available vaccines in Europe consist of highly purified inactivated whole TBE virus. Austria is the country with the highest coverage of TBE vaccination (86% of the total population) and this has led to a dramatic reduction in the annual number of clinical cases and proves under field conditions that vaccination is an effective means for the prophylaxis of TBE.

The entry machinery of flaviviruses

We have been using the flavivirus tick-borne encephalitis virus (TBEV) as a model system for investigating the molecular mechanisms underlying the membrane fusion process mediated by a class II viral fusion protein, the flavivirus envelope protein E. In the mature virion this protein exists as a metastable dimer that dissociates at the acidic pH in endosomes and is converted into a more stable trimeric conformation. The dimer dissociation step liberates an internal fusion peptide that interacts with the target endosomal membrane, and then further conformational changes are believed to drive membrane fusion. Although flavivirus fusion appears to be a more facile and efficient process than that of alphaviruses, which also possess a class II viral fusion protein, the fusion mechanism in both viral systems involves structurally related interactions with lipids, specifically the 3beta-hydroxyl group at C3 of cholesterol. The class II viral fusion machineries are structurally different from those involving class I viral fusion proteins, such as those found in orthomyxoviruses, paramyxoviruses, retroviruses, and filoviruses, but have certain similarities in common with bacterial pore-forming proteins.

Two distinct size classes of immature and mature subviral particles from tick-borne encephalitis virus

Flaviviruses assemble in the endoplasmic reticulum by a mechanism that appears to be driven by lateral interactions between heterodimers of the envelope glycoproteins E and prM. Immature intracellular virus particles are then transported through the secretory pathway and converted to their mature form by cleavage of the prM protein by the cellular protease furin. Earlier studies showed that when the prM and E proteins of tick-borne encephalitis virus are expressed together in mammalian cells, they assemble into membrane-containing, icosahedrally symmetrical recombinant subviral particles (RSPs), which are smaller than whole virions but retain functional properties and undergo cleavage maturation, yielding a mature form in which the E proteins are arranged in a regular T = 1 icosahedral lattice. In this study, we generated immature subviral particles by mutation of the furin recognition site in prM. The mutation resulted in the secretion of two distinct size classes of particles that could be separated by sucrose gradient centrifugation. Electron microscopy showed that the smaller particles were approximately the same size as the previously described mature RSPs, whereas the larger particles were approximately the same size as the virus. Particles of the larger size class were also detected with a wild-type construct that allowed prM cleavage, although in this case the smaller size class was far more prevalent. Subtle differences in endoglycosidase sensitivity patterns suggested that, in contrast to the small particles, the E glycoproteins in the large subviral particles and whole virions might be in nonequivalent structural environments during intracellular transport, with a portion of them inaccessible to cellular glycan processing enzymes. These proteins thus appear to have the intrinsic ability to form alternative assembly products that could provide important clues about the role of lateral envelope protein interactions in flavivirus assembly.

Incorporation of tick-borne encephalitis virus replicons into virus-like particles by a packaging cell line

RNA replicons derived from flavivirus genomes show considerable potential as gene transfer and immunization vectors. A convenient and efficient encapsidation system is an important prerequisite for the practical application of such vectors. In this work, tick-borne encephalitis (TBE) virus replicons and an appropriate packaging cell line were constructed and characterized. A stable CHO cell line constitutively expressing the two surface proteins prM/M and E (named CHO-ME cells) was generated and shown to efficiently export mature recombinant subviral particles (RSPs). When replicon NdDeltaME lacking the prM/M and E genes was introduced into CHO-ME cells, virus-like particles (VLPs) capable of initiating a single round of infection were released, yielding titers of up to 5 x 10(7)/ml in the supernatant of these cells. Another replicon (NdDeltaCME) lacking the region encoding most of the capsid protein C in addition to proteins prM/M and E was not packaged by CHO-ME cells. As observed with other flavivirus replicons, both TBE virus replicons appeared to exert no cytopathic effect on their host cells. Sedimentation analysis revealed that the NdDeltaME-containing VLPs were physically distinct from RSPs and similar to infectious virions. VLPs could be repeatedly passaged in CHO-ME cells but maintained the property of being able to initiate only a single round of infection in other cells during these passages. CHO-ME cells can thus be used both as a source for mature TBE virus RSPs and as a safe and convenient replicon packaging cell line, providing the TBE virus surface proteins prM/M and E in trans.