Membrane Topology of Pestiviral Non-Structural Protein 2 and determination of the minimal autoprotease domain.

Pestiviruses like bovine viral diarrhea virus (BVDV) belong to the family Flaviviridae A distinctive feature of the Flaviviridae is the importance of non-structural (NS) proteins for RNA genome replication and virus morphogenesis. For pestiviruses, the NS2 protease-mediated release of NS3 is essential for RNA replication, whereas uncleaved NS2-3 is indispensable for producing viral progeny. Accordingly, in the pestiviral life cycle the switch from RNA replication to virion morphogenesis is temporally regulated by the extent of NS2-3 cleavage, which is catalyzed by the NS2 autoprotease. A detailed knowledge of the structural and functional properties of pestiviral NS2 and NS2-3 is mandatory for a better understanding of these processes.In the present study, we experimentally determined the membrane topology of NS2 of BVDV-1 strain NCP7 by the Substituted Cysteine Accessibility Method (SCAM) assay. According to the resulting model, the N terminus of NS2 resides in the ER lumen and is followed by three transmembrane segments (TM) and a cytoplasmic C-terminal protease domain. We used the resulting model for fine mapping of the minimal autoprotease domain. Only one TM segment was found to be essential for maintaining residual autoprotease activity. While the topology of pestiviral NS2 is overall comparable to the one of hepatitis C virus (HCV) NS2, our data also reveal potentially important differences between the two molecules. The improved knowledge about structural and functional properties of this protein will support future functional and structural studies on pestiviral NS2.ImportancePestiviral NS2 is central to the regulation of RNA replication and virion morphogenesis via its autoprotease activity. This activity is temporally regulated by the cellular DNAJC14 as a cofactor: while free NS3 is required for RNA replication as a component of the viral replicase, only uncleaved NS2-3 supports virion morphogenesis. For a better understanding of the underlying molecular interactions, topological and structural data are required. The topology-based determination of the minimal NS2-protease domain in the present study will facilitate future attempts to determine the structure of this unusual protease cofactor complex. In the hepatitis C virus system, NS2 functions as a hub in virion morphogenesis by interacting with structural as well as non-structural proteins. Our knowledge of the membrane topology will significantly support future detailed interaction studies for pestiviral NS2.

Determination of Critical Requirements for Classical Swine Fever Virus NS2-3-Independent Virion Formation.

For members of the Flaviviridae, it is known that, besides the structural proteins, nonstructural (NS) proteins also play a critical role in virion formation. Pestiviruses, such as bovine viral diarrhea virus (BVDV), rely on uncleaved NS2-3 for virion formation, while its cleavage product, NS3, is selectively active in RNA replication. This dogma was recently challenged by the selection of gain-of-function mutations in NS2 and NS3 which allowed virion formation in the absence of uncleaved NS2-3 in BVDV type 1 (BVDV-1) variants encoding either a ubiquitin (Ubi) (NS2-Ubi-NS3) or an internal ribosome entry site (IRES) (NS2-IRES-NS3) between NS2 and NS3. To determine whether the ability to adapt to NS2-3-independent virion morphogenesis is conserved among pestiviruses, we studied the corresponding NS2 and NS3 mutations (2/T444-V and 3/M132-A) in classical swine fever virus (CSFV). We observed that these mutations were capable of restoring low-level NS2-3-independent virion formation only for CSFV NS2-Ubi-NS3. Interestingly, a second NS2 mutation (V439-D), identified by selection, was essential for high-titer virion production. Similar to previous findings for BVDV-1, these mutations in NS2 and NS3 allowed for low-titer virion production only in CSFV NS2-IRES-NS3. For efficient virion morphogenesis, additional exchanges in NS4A (A48-T) and NS5B (D280-G) were required, indicating that these proteins cooperate in NS2-3-independent virion formation. Interestingly, both NS5B mutations, selected independently for NS2-IRES-NS3 variants of BVDV-1 and CSFV, are located in the fingertip region of the viral RNA-dependent RNA polymerase, classifying this structural element as a novel determinant for pestiviral NS2-3-independent virion formation. Together, these findings will stimulate further mechanistic studies on the genome packaging of pestiviruses.IMPORTANCE For Flaviviridae members, the nonstructural proteins are essential for virion formation and thus exert a dual role in RNA replication and virion morphogenesis. However, it remains unclear how these proteins are functionalized for either process. In wild-type pestiviruses, the NS3/4A complex is selectively active in RNA replication, while NS2-3/4A is essential for virion formation. Mutations recently identified in BVDV-1 rendered NS3/4A capable of supporting NS2-3-independent virion morphogenesis. A comparison of NS3/4A complexes incapable/capable of supporting virion morphogenesis revealed that changes in NS3/NS4A surface interactions are decisive for the gain of function. However, so far, the role of the NS2 mutations as well as the accessory mutations additionally required in the NS2-IRES-NS3 virus variant has not been clarified. To unravel the course of genome packaging, the additional sets of mutations obtained for a second pestivirus species (CSFV) are of significant importance to develop mechanistic models for this complex process.

Characterization of the Determinants of NS2-3-Independent Virion Morphogenesis of Pestiviruses.

UNLABELLED: A peculiarity of the Flaviviridae is the critical function of nonstructural (NS) proteins for virus particle formation. For pestiviruses, like bovine viral diarrhea virus (BVDV), uncleaved NS2-3 represents an essential factor for virion morphogenesis, while NS3 is an essential component of the viral replicase. Accordingly, in natural pestivirus isolates, processing at the NS2-3 cleavage site is not complete, to allow for virion morphogenesis. Virion morphogenesis of the related hepatitis C virus (HCV) shows a major deviation from that of pestiviruses: while RNA replication also requires free NS3, virion formation does not depend on uncleaved NS2-NS3. Recently, we described a BVDV-1 chimera based on strain NCP7 encompassing the NS2-4B*-coding region of strain Osloss (E. Lattwein, O. Klemens, S. Schwindt, P. Becher, and N. Tautz, J Virol 86:427-437, 2012, doi:10.1128/JVI.06133-11). This chimera allowed for the production of infectious virus particles in the absence of uncleaved NS2-3. The Osloss sequence deviates in the NS2-4B* part from NCP7 in 48 amino acids and also has a ubiquitin insertion between NS2 and NS3. The present study demonstrates that in the NCP7 backbone, only two amino acid exchanges in NS2 (E1576V) and NS3 (V1721A) are sufficient and necessary to allow for efficient NS2-3-independent virion morphogenesis. The adaptation of a bicistronic virus encompassing an internal ribosomal entry site element between the NS2 and NS3 coding sequences to efficient virion morphogenesis led to the identification of additional amino acids in E2, NS2, and NS5B that are critically involved in this process. The surprisingly small requirements for approximating the packaging schemes of pestiviruses and HCV with respect to the NS2-3 region is in favor of a common mechanism in an ancestral virus. IMPORTANCE: For positive-strand RNA viruses, the processing products of the viral polyprotein serve in RNA replication as well as virion morphogenesis. For bovine viral diarrhea virus, nonstructural protein NS2-3 is of critical importance to switch between these processes. While free NS3 is essential for RNA replication, uncleaved NS2-3, which accumulates over time in the infected cell, is required for virion morphogenesis. In contrast, the virion morphogenesis of the related hepatitis C virus is independent from uncleaved NS2-NS3. Here, we demonstrate that pestiviruses can adapt to virion morphogenesis in the absence of uncleaved NS2-3 by just two amino acid exchanges. While the mechanism behind this gain of function remains elusive, the fact that it can be achieved by such minor changes is in line with the assumption that an ancestral virus already used this mechanism but lost it in the course of adapting to a new host/infection strategy.

Pestivirus virion morphogenesis in the absence of uncleaved nonstructural protein 2-3.

The family Flaviviridae contains three genera of positive-strand RNA viruses, namely, Flavivirus, Hepacivirus (e.g., hepatitis C virus [HCV]), and Pestivirus. Pestiviruses, like bovine viral diarrhea virus (BVDV), bear a striking degree of similarity to HCV concerning polyprotein organization, processing, and function. Along this line, in both systems, release of nonstructural protein 3 (NS3) is essential for viral RNA replication. However, both viruses differ significantly with respect to processing efficiency at the NS2/3 cleavage site and abundance as well as functional relevance of uncleaved NS2-3. In BVDV-infected cells, significant amounts of NS2-3 accumulate at late time points postinfection and play an essential but ill-defined role in the production of infectious virions. In contrast, complete cleavage of the HCV NS2-3 counterpart has been reported, and unprocessed NS2-3 is not required throughout the life cycle of HCV, at least in cell culture. Here we describe the selection and characterization of the first pestiviral genome with the capability to complete productive infection in the absence of uncleaved NS2-3. Despite the insertion of a ubiquitin gene or an internal ribosomal entry site between the NS2 and NS3 coding sequences, the selected chimeric BVDV-1 genomes gave rise to infectious virus progeny. In this context, a mutation in the N-terminal third of NS2 was identified as a critical determinant for efficient production of infectious virions in the absence of uncleaved NS2-3. These findings challenge a previously accepted dogma for pestivirus replication and provide new implications for virion morphogenesis of pestiviruses and HCV.