A novel NS3/4A protease dependent cleavage site within pestiviral NS2.

Pestiviruses like bovine viral diarrhoea virus (BVDV) and classical swine fever virus (CSFV) belong to the family Flaviviridae. A special feature of the Flaviviridae is the importance of nonstructural (NS) proteins for both genome replication and virion morphogenesis. The NS2-3-4A region and its regulated processing by the NS2 autoprotease and the NS3/4A protease plays a central role in the pestiviral life cycle. We report the identification and characterization of a novel internal cleavage in BVDV NS2, which is mediated by the NS3/4A protease. Further mapping using the NS2 of BVDV-1 strain NCP7 showed that cleavage occurs between L188 and G189. This cleavage site represents a novel sequence motif recognized by the NS3/4A protease and is conserved between the pestivirus species A, B and D. Inhibition of this internal NS2 cleavage by mutating the cleavage site did not cause obvious effects on RNA replication or virion morphogenesis in cultured cell lines. Accordingly, this novel internal NS2 cleavage adds an additional layer to the already complex polyprotein processing of Pestiviruses and might further extend the repertoires of the multifunctional NS2. However, unravelling of the functional relevance of this novel processing event in NS2, therefore, awaits future in vivo studies.

The Erns Carboxyterminus: Much More Than a Membrane Anchor.

Pestiviruses express the unique essential envelope protein Erns, which exhibits RNase activity, is attached to membranes by a long amphipathic helix, and is partially secreted from infected cells. The RNase activity of Erns is directly connected with pestivirus virulence. Formation of homodimers and secretion of the protein are hypothesized to be important for its role as a virulence factor, which impairs the host's innate immune response to pestivirus infection. The unusual membrane anchor of Erns raises questions with regard to proteolytic processing of the viral polyprotein at the Erns carboxy-terminus. Moreover, the membrane anchor is crucial for establishing the critical equilibrium between retention and secretion and ensures intracellular accumulation of the protein at the site of virus budding so that it is available to serve both as structural component of the virion and factor controlling host immune reactions. In the present manuscript, we summarize published as well as new data on the molecular features of Erns including aspects of its interplay with the other two envelope proteins with a special focus on the biochemistry of the Erns membrane anchor.

About the necessity of including HoBi-like pestiviruses in bovine respiratory and reproductive viral vacines / Sobre a necessidade de incluir pestivírus HoBi-like em vacinas virais respiratórias e reprodutivas para bovinos

HoBi-like pestiviruses (HoBiPeV) constitute a novel group of bovine pestiviruses, genetically and antigenically related to bovine viral diarrhea virus 1 (BVDV-1) and BVDV-2. Recent data shows that HoBiPeV are endemic among Brazilian cattle, yet bovine reproductive/respiratory vaccines contain only BVDV-1 and BVDV-2 strains. The present study investigated the neutralizing antibody response against these pestiviruses induced by two commercial vaccines (VA = attenuated, VI = inactivated) and by three experimental, replicative, vaccine formulations (VAC1 = monovalent, BVDV-1; VAC2 = bivalent, BVDV-1 + BVDV-2; VAC3 = trivalent, BVDV-1 + BVDV-2 and HoBiPeV). Seronegative beef calves were immunized once (replicative vaccines) or twice (inactivated vaccine) and serum samples were tested by virus-neutralization (VN) 30 days after vaccination (dpv) (replicative vaccines) or 30 days after the second dose (VI). We considered a threshold VN titer of ≥60 indicative of protection against clinical disease. At 30 dpv, VA induced protective titers against BVDV-2 in 7/7 animals (GMT=289.8) and against BVDV-1 and HoBiPeV in 5/7 animals (GMTs=97.5 and 80, respectively). VI induced protective titers against BVDV-1 in 1/7 animal (GMT=16.4), 2/7 animals against BVDV-2 (GMT=53.8) and in none of the calves against HoBiPeV (GMT=12.2). When a pool of sera of each vaccine group was tested against individual Brazilian isolates, VA induced protective titers against 3/7 BVDV-1 isolates, to 9/10 (BVDV-2) and 1/8 (HoBiPeV); VI induced protective titers against 1/7 (BVDV-1), 1/10 (BVDV-2) and none (0/8) HoBiPeV isolates. The experimental vaccine VAC1 induced protective titers against BVDV-1 in 9/9 animals (GMT=320) but in no animal against BVDV-2 or HoBiPeV (GMT<10). VAC2 induced protective titers to BVDV-1 and BVDV-2 in 9/9 animals (GMTs=160 and 640, respectively), and against HoBiPeV in 7/9 animals (GMT=108.5). Finally, VAC3 induced protective titers in all animals against BVDV-1 (GMT=234.3), BVDV-2 (294.9) and HoBiPeV (201.1). Testing the pool of sera against pestivirus isolates, VAC1 induced titers ≥ 60 against 4/7 BVDV-1 but to none BVDV-2/HoBiPeV isolate; VAC2 induced protective titers against 4/7 BVDV-1; 10/10 BVDV-2 and 2/8 HoBiPeV; VAC3 induced protective titers against all BVDV-1, BVDV-2 and HoBiPeV isolates. These results indicate that vaccines composed by BVDV-1+BVDV-2, especially those containing inactivated virus, may not induce serological response against a variety of HoBiPeV isolates. Thus, the need of inclusion of HoBiPeV in vaccine formulations should be considered.(AU)

Os pestivírus HoBi-like (HoBiPeV) compõe um grupo novo de pestivírus de bovinos, genética e antigenicamente relacionados com os vírus da diarreia viral bovina 1 e 2 (BVDV-1, BVDV2). Dados recentes indicam que os HoBiPeV são endêmicos na população bovina do Brasil, mas as vacinas respiratórias e reprodutivas bovinas contêm apenas cepas de BVDV-1 e BVDV-2. O presente estudo investigou a atividade neutralizante contra estes pestivírus induzidas por duas vacinas comerciais (VA = atenuada, VI = inativada) e por três vacinas experimentais replicativas (VAC1 = monovalente, BVDV-1; VAC2 = bivalente, BVDV-1 + BVDV-2; VAC3 = trivalente, BVDV-1 + BVDV-2 e HoBiPeV). Bezerros soronegativos foram imunizados uma vez (vacinas replicativas) ou duas (vacina inativada) e amostras de soro foram testadas por vírus-neutralização (VN) 30 dias após a vacinação (dpv) (vacinas replicativas) ou 30 dias após a segunda dose (VI). Títulos neutralizantes ≥60 foram considerados indicativos de proteção contra doença clínica. Nesta data, a VA induziu títulos protetivos contra o BVDV-2 em 7/7 animais (GMT=289,8) e contra BVDV-1 e HoBiPeV em 5/7 animals (GMTs=97,5 e 80, respectivamente). VI induziu títulos protetores contra BVDV-1 em 1/7 animal (GMT=16,4), em 2/7 animais contra BVDV-2 (GMT=53,8) e em nenhum contra HoBiPeV (GMT=12,2). Quando um pool de soro de cada grupo vacinal foi testado frente a isolados Brasileiros, a VA induziu títulos protetores contra 3/7 isolados de BVDV-1, 9/10 (BVDV-2) e 1/8 (HoBiPeV); VI induziu títulos protetores em 1/7 contra BVDV-1, 1/10 (BVDV-2) e em nenhum (0/8) contra isolados de HoBiPeV. A VAC1 induziu títulos protetores contra BVDV-1 em 9/9 animais (GMT=320) mas em nenhum animal contra BVDV-2 ou HoBiPeV (GMT<10). VAC2 induziu títulos protetores contra BVDV-1e BVDV-2 em 9/9 animais (GMTs=160 e 640, respectivamente),e contra HoBiPeV em 7/9 animais (GMT=108,5). Finalmente, VAC3 induziu títulos protetores em todos os animais contra BVDV-1 (GMT=234,3), BVDV-2 (294,9) e HoBiPeV (201,1). No teste de pool de soro contra isolados de pestivírus, VAC1 induziu títulos ≥60 contra 4/7 BVDV-1 mas contra nenhum isolado de BVDV-2/HoBiPeV; VAC2 induziu títulos protetores contra 4/7 BVDV-1; 10/10 BVDV-2 e 2/8 HoBiPeV; VAC3 induziu títulos protetores contra todos BVDV-1, BVDV-2 e HoBiPeV. Esses resultados indicam que vacinas contendo apenas BVDV-1 BVDV-2, especialmente aquelas inativadas, podem não conferir resposta sorológica protetora contra vários isolados de HoBiPeV. Portanto, a necessidade de se incluir cepas de HoBiPeV nas vacinas deve ser considerada.(AU)

A positive-strand RNA virus uses alternative protein-protein interactions within a viral protease/cofactor complex to switch between RNA replication and virion morphogenesis.

The viruses of the family Flaviviridae possess a positive-strand RNA genome and express a single polyprotein which is processed into functional proteins. Initially, the nonstructural (NS) proteins, which are not part of the virions, form complexes capable of genome replication. Later on, the NS proteins also play a critical role in virion formation. The molecular basis to understand how the same proteins form different complexes required in both processes is so far unknown. For pestiviruses, uncleaved NS2-3 is essential for virion morphogenesis while NS3 is required for RNA replication but is not functional in viral assembly. Recently, we identified two gain of function mutations, located in the C-terminal region of NS2 and in the serine protease domain of NS3 (NS3 residue 132), which allow NS2 and NS3 to substitute for uncleaved NS2-3 in particle assembly. We report here the crystal structure of pestivirus NS3-4A showing that the NS3 residue 132 maps to a surface patch interacting with the C-terminal region of NS4A (NS4A-kink region) suggesting a critical role of this contact in virion morphogenesis. We show that destabilization of this interaction, either by alanine exchanges at this NS3/4A-kink interface, led to a gain of function of the NS3/4A complex in particle formation. In contrast, RNA replication and thus replicase assembly requires a stable association between NS3 and the NS4A-kink region. Thus, we propose that two variants of NS3/4A complexes exist in pestivirus infected cells each representing a basic building block required for either RNA replication or virion morphogenesis. This could be further corroborated by trans-complementation studies with a replication-defective NS3/4A double mutant that was still functional in viral assembly. Our observations illustrate the presence of alternative overlapping surfaces providing different contacts between the same proteins, allowing the switch from RNA replication to virion formation.

Lipid Binding of the Amphipathic Helix Serving as Membrane Anchor of Pestivirus Glycoprotein Erns.

Pestiviruses express a peculiar protein named Erns representing envelope glycoprotein and RNase, which is important for control of the innate immune response and persistent infection. The latter functions are connected with secretion of a certain amount of Erns from the infected cell. Retention/secretion of Erns is most likely controlled by its unusual membrane anchor, a long amphipathic helix attached in plane to the membrane. Here we present results of experiments conducted with a lipid vesicle sedimentation assay able to separate lipid-bound from unbound protein dissolved in the water phase. Using this technique we show that a protein composed of tag sequences and the carboxyterminal 65 residues of Erns binds specifically to membrane vesicles with a clear preference for compositions containing negatively charged lipids. Mutations disturbing the helical folding and/or amphipathic character of the anchor as well as diverse truncations and exchange of amino acids important for intracellular retention of Erns had no or only small effects on the proteins membrane binding. This result contrasts the dramatically increased secretion rates observed for Erns proteins with equivalent mutations within cells. Accordingly, the ratio of secreted versus cell retained Erns is not determined by the lipid affinity of the membrane anchor.

Structures and Functions of Pestivirus Glycoproteins: Not Simply Surface Matters.

Pestiviruses, which include economically important animal pathogens such as bovine viral diarrhea virus and classical swine fever virus, possess three envelope glycoproteins, namely Erns, E1, and E2. This article discusses the structures and functions of these glycoproteins and their effects on viral pathogenicity in cells in culture and in animal hosts. E2 is the most important structural protein as it interacts with cell surface receptors that determine cell tropism and induces neutralizing antibody and cytotoxic T-lymphocyte responses. All three glycoproteins are involved in virus attachment and entry into target cells. E1-E2 heterodimers are essential for viral entry and infectivity. Erns is unique because it possesses intrinsic ribonuclease (RNase) activity that can inhibit the production of type I interferons and assist in the development of persistent infections. These glycoproteins are localized to the virion surface; however, variations in amino acids and antigenic structures, disulfide bond formation, glycosylation, and RNase activity can ultimately affect the virulence of pestiviruses in animals. Along with mutations that are driven by selection pressure, antigenic differences in glycoproteins influence the efficacy of vaccines and determine the appropriateness of the vaccines that are currently being used in the field.

Structural models of the membrane anchors of envelope glycoproteins E1 and E2 from pestiviruses.

The membrane anchors of viral envelope proteins play essential roles in cell entry. Recent crystal structures of the ectodomain of envelope protein E2 from a pestivirus suggest that E2 belongs to a novel structural class of membrane fusion machinery. Based on geometric constraints from the E2 structures, we generated atomic models of the E1 and E2 membrane anchors using computational approaches. The E1 anchor contains two amphipathic perimembrane helices and one transmembrane helix; the E2 anchor contains a short helical hairpin stabilized in the membrane by an arginine residue, similar to flaviviruses. A pair of histidine residues in the E2 ectodomain may participate in pH sensing. The proposed atomic models point to Cys987 in E2 as the site of disulfide bond linkage with E1 to form E1-E2 heterodimers. The membrane anchor models provide structural constraints for the disulfide bonding pattern and overall backbone conformation of the E1 ectodomain.

Autocatalytic activity and substrate specificity of the pestivirus N-terminal protease Npro.

Pestivirus N(pro) is the first protein translated in the viral polypeptide, and cleaves itself off co-translationally generating the N-terminus of the core protein. Once released, N(pro) blocks the host׳s interferon response by inducing degradation of interferon regulatory factor-3. N(pro׳)s intracellular autocatalytic activity and lack of trans-activity have hampered in vitro cleavage studies to establish its substrate specificity and the roles of individual residues. We constructed N(pro)-GFP fusion proteins that carry the authentic cleavage site and determined the autoproteolytic activities of N(pro) proteins containing substitutions at the predicted catalytic sites Glu22 and Cys69, at Arg100 that forms a salt bridge with Glu22, and at the cleavage site Cys168. Contrary to previous reports, we show that N(pro׳)s catalytic activity does not involve Glu22, which may instead be involved in protein stability. Furthermore, N(pro) does not have specificity for Cys168 at the cleavage site even though this residue is conserved throughout the pestivirus genus.

Structure of the membrane anchor of pestivirus glycoprotein E(rns), a long tilted amphipathic helix.

E(rns) is an essential virion glycoprotein with RNase activity that suppresses host cellular innate immune responses upon being partially secreted from the infected cells. Its unusual C-terminus plays multiple roles, as the amphiphilic helix acts as a membrane anchor, as a signal peptidase cleavage site, and as a retention/secretion signal. We analyzed the structure and membrane binding properties of this sequence to gain a better understanding of the underlying mechanisms. CD spectroscopy in different setups, as well as Monte Carlo and molecular dynamics simulations confirmed the helical folding and showed that the helix is accommodated in the amphiphilic region of the lipid bilayer with a slight tilt rather than lying parallel to the surface. This model was confirmed by NMR analyses that also identified a central stretch of 15 residues within the helix that is fully shielded from the aqueous layer, which is C-terminally followed by a putative hairpin structure. These findings explain the strong membrane binding of the protein and provide clues to establishing the E(rns) membrane contact, processing and secretion.

A novel membrane fusion protein family in Flaviviridae?

Enveloped viruses must fuse their lipid membrane to a cellular membrane to deliver their genome into the cytoplasm for replication. Viral envelope proteins catalyze this critical membrane fusion event. They fall into three distinct structural classes. In 2013, envelope proteins from a pestivirus and hepatitis C virus were found to have two distinct novel folds. This was unexpected because these viruses are in the same family as flaviviruses, which have class II fusion proteins. We propose that the membrane fusion machinery of the closely related pestiviruses and hepatitis C virus defines a new structural class. This and other recently identified structural relationships between viral fusion proteins shift the paradigm for how these proteins evolved.

The pestivirus glycoprotein Erns is anchored in plane in the membrane via an amphipathic helix.

E(rns) is a structural glycoprotein of pestiviruses found to be attached to the virion and to membranes within infected cells via its COOH terminus, although it lacks a hydrophobic anchor sequence. The COOH-terminal sequence was hypothesized to fold into an amphipathic alpha-helix. Alanine insertion scanning revealed that the ability of the E(rns) COOH terminus to bind membranes is considerably reduced by the insertion of a single amino acid at a wide variety of positions. Mutations decreasing the hydrophobicity of the apolar face of the putative helix led to reduction of membrane association. Proteinase K protection assays showed that E(rns) translated in vitro in the presence of microsomal membranes was protected, whereas a mutant with an artificial transmembrane region and a short cytosolic tag was shortened by the protease treatment. A tag fused to the COOH terminus of wild type E(rns) was not accessible for antibodies within digitonin-permeabilized cells, but the variant with the tag located downstream of the artificial transmembrane region was detected under the same conditions. These results are in accordance with the model that the COOH-terminal membrane anchor of E(rns) represents an amphipathic helix embedded in plane into the membrane. The integrity of the membrane anchor was found to be important for recovery of infectious virus.

A distinct group of hepacivirus/pestivirus-like internal ribosomal entry sites in members of diverse picornavirus genera: evidence for modular exchange of functional noncoding RNA elements by recombination.

The 5' untranslated regions (UTRs) of the RNA genomes of Flaviviridae of the Hepacivirus and Pestivirus genera contain internal ribosomal entry sites (IRESs) that are unrelated to the two principal classes of IRESs of Picornaviridae. The mechanism of translation initiation on hepacivirus/pestivirus (HP) IRESs, which involves factor-independent binding to ribosomal 40S subunits, also differs fundamentally from initiation on these picornavirus IRESs. Ribosomal binding to HP IRESs requires conserved sequences that form a pseudoknot and the adjacent IIId and IIIe domains; analogous elements do not occur in the two principal groups of picornavirus IRESs. Here, comparative sequence analysis was used to identify a subset of picornaviruses from multiple genera that contain 5' UTR sequences with significant similarities to HP IRESs. They are avian encephalomyelitis virus, duck hepatitis virus 1, duck picornavirus, porcine teschovirus, porcine enterovirus 8, Seneca Valley virus, and simian picornavirus. Their 5' UTRs are predicted to form several structures, in some of which the peripheral elements differ from the corresponding HP IRES elements but in which the core pseudoknot, domain IIId, and domain IIIe elements are all closely related. These findings suggest that HP-like IRESs have been exchanged between unrelated virus families by recombination and support the hypothesis that RNA viruses consist of modular coding and noncoding elements that can exchange and evolve independently.

Comparison of the complete genomic sequence of the border disease virus, BD31, to other pestiviruses.

The genus Pestivirus is composed of hog cholera virus (HCV) [also known as classical swine fever virus (CSFV)], bovine viral diarrhea virus (BVDV), and border disease virus (BDV). Complete sequences have been published for HCV (or CSFV) and the two genotypes of BVDV (BVDV1 and BVDV2). In this study the complete sequence of the border disease virus (BDV), BD31, was determined. BD31 was isolated from a lamb with hairy shaker syndrome and is the BDV type virus offered by ATCC (ATCC VR-996). The genome was 12268 nucleotides long and had a single large open reading frame (ORF) beginning at nucleotide 357 and ending at nucleotide 12045. The sequence identity of the predicted amino acid sequence of BD31 and other published pestivirus sequences varied from 71% to 78%. Phylogenetic analysis of available complete genomic sequences segregated pestiviruses into two branches. One branch contained BD31 and HCV (or CSFV) isolates while the other branch contained BVDV1 and BVDV2 isolates. Pestiviruses from the same branch were similar in the length of the 5' and 3' untranslated regions (UTR). When complete genomic sequences were compared among BD31, HCV (or CSFV), BVDV1 and BVDV2, the highest sequence identity was observed in the 5' UTR. Within the ORF, the highest sequence identity was observed in the genomic region coding for the nonstructural viral polypeptide p80.

Ruminant pestiviruses.

The ruminant pestiviruses, bovine virus diarrhoea virus (BVDV) and border disease virus (BDV) are highly successful and important pathogens which infect ruminant species worldwide. Although the serological relationships among ruminant pestiviruses require further clarification, there is growing evidence for two antigenic groups, one of which predominates in cattle and one in sheep. The success of pestiviruses stems from the ability of the non-cytopathic (NCP) biotype of the virus to cross the placenta and establish a persistent infection (PI) in the developing foetus. This biotype should be regarded as the 'normal' biotype with the cytopathic (CP) biotype being an abnormal virus that is usually isolated only from PI animals dying from mucosal disease. Recent molecular evidence points to CP viruses arising from their NCP counterparts by recombination events that include the insertion of host RNA and/or the duplication of viral RNA sequences. However, the biological mechanism through which CP viruses kill cells remains unknown. Virtually all CP and NCP viruses cause only mild, transient clinical symptoms in healthy adult animals and stimulate a protective immune response. Despite the urgent requirement for a safe, effective vaccine, there is still no commercial vaccine that has been shown to immunize dams so that foetal infection is prevented. In the absence of an effective vaccine, reliable diagnostic techniques are essential to implement effective control measures. There is now a range of monoclonal antibody-based enzyme-linked immunosorbent assays for identifying PI or convalescent animals. These tests are specific, rapid, sensitive and reliable but may themselves become redundant as they are superceded by ever-increasing molecular biology-based techniques.

Epitope mapping of envelope glycoprotein E1 of hog cholera virus strain Brescia.

Four antigenic domains (A, B, C and D) on envelope glycoprotein E1 (gp51-54) of hog cholera virus strain Brescia have been specified by using 13 monoclonal antibodies (MAbs) that recognize non-conserved and conserved epitopes. It was shown that the non-conserved epitopes map to the N-terminal half of E1 by analysis of chimeric E1 proteins of strains Brescia and C. Conserved epitopes, however, could not be mapped using this approach. Here we describe mapping of both conserved and non-conserved epitopes on E1 by the use of an extensive set of single and double deletion mutants of E1 of strain Brescia. Deletion mutants were transiently expressed in COS1 cells and analysed by immunostaining with the 13 MAbs directed against strain Brescia and four MAbs directed against strain C. All MAbs bound to the N-terminal half of E1, i.e. amino acids 690 to 866 encoded by the sequence of strain Brescia. Domain B and one epitope in domain C are located between residues 690 and 773. Other epitopes in domain C are located on an extended region, i.e. between residues 690 and 800. Conserved epitopes of domain A are mapped between residues 766 and 866, whereas the only non-conserved epitope in this domain is located between residues 766 and 813. Domain D, represented by one MAb, is located in the same region as this non-conserved epitope of domain A, i.e. between residues 766 and 800. The results suggest the presence of two distinct antigenic units on E1, one consisting of domains B and C and the other consisting of domain A.

Proteins encoded in the 5' region of the pestivirus genome--considerations concerning taxonomy.

The first protein encoded within the pestivirus open reading frame is a nonstructural protein which removes itself from the polyprotein by autoproteolytic cleavage. The following nucleocapsid protein ends just before a putative signal sequence preceding three glycosylated proteins. All three glycoproteins are part of the viral envelope and exist in the form of disulfide-linked dimers. Pestiviruses have recently been reclassified as members of the family Flaviviridae which now comprises three genera, namely flavivirus, hepatitis C virus group and pestivirus. All members of the family have certain characteristics in common like the overall genome organization and the strategy of gene expression. Major differences exist, however, between the genera; the most obvious ones concern proteins encoded in the 5' region of the respective genomes.

Characterisation of p20 gene sequences from a border disease-like pestivirus isolated from pigs.

A pestivirus, isolated from pigs with haemorrhagic lesions, was antigenically more similar to border disease (BD) virus than to either hog cholera (HC) or bovine viral diarrhoea (BVD) viruses. After reverse transcription the genome at the 5' end, along with the same region from a BD isolate from sheep, was amplified by the polymerase chain reaction and cloned. The region of the p20 gene was sequenced and compared with published data for BVD and HC viruses. A number of motifs were conserved in the amino acid sequences of all the viruses. The pig isolate had a greater degree of homology in this region with the BD isolate (87%) than with BVD (73%) or HC (74%) viruses. This further confirms the BD-like nature of the virus.