Pestiviruses isolated from pigs, cattle and sheep can be allocated into at least three genogroups using polymerase chain reaction and restriction endonuclease analysis

A polymerase chain reaction-based assay capable of detecting a broad range of pestiviruses from pigs, cattle, or sheep was developed. Of six sets of primers selected from different parts of the pestivirus genome, the best results were provided by a pair from the highly conserved 5' non-coding region which gave amplification with all 129 isolates tested. This panel consisted of 33 isolates from pigs, 79 from cattle, and 17 from sheep. Differentiation between the viruses was achieved by cutting the PCR-amplified products with the restriction endonucleases AvaI and Bg1I. Using this procedure it was possible to distinguish at least 3 genogroups; group 1 (HCV) contained 32 of the pig isolates, group II (BVDV) contained all the cattle isolates tested plus 6 sheep isolates and group III (BDV) contained 11 sheep isolates and 1 pig isolate.

Variable and hypervariable domains are found in the regions of HCV corresponding to the flavivirus envelope and NS1 proteins and the pestivirus envelope glycoproteins

Based on the flavi- and pestivirus model of genome organization for the hepatitis C virus (HCV) (1-5), the nucleotide and deduced amino acid sequences of the putative envelope (E1) and the junction between the E1 and NS1/envelope 2 (E2) region from six different human isolates of HCV were compared with the nucleotide and predicted amino acid sequences of the prototype hepatitis C virus (HCV-1) (5). The overall percentage of nucleotide and amino acid changes among all six isolates, including HCV-1, from nucleotide 713 to 1630 (amino acid 129 to 437) was between 3 and 7%, which is comparable to that seen in some flaviviruses (6-8). An analysis of the number of nucleotide and deduced amino acid sequence changes among all six isolates and HCV-1 revealed a moderately variable domain of approximately 40 amino acids in the E1 region and a hypervariable domain (Region V) of approximately 28 amino acids, which is directly downstream from a putative signal peptide sequence, in the junction between E1 and NS1/E2. A similar hypervariable domain is not found in the C-terminus of the envelope polypeptide or in the N-terminus of the NS1 polypeptide domain of the flaviviruses. These findings suggest that the mature NS1/E2 polypeptide starts about amino acid 380 and that the NS1/E2 domain may correspond to a second envelope glycoprotein as in the case of the pestivirus. The observed heterogeneity in the putative structural proteins of HCV may have important ramifications for future vaccine development.

Hepatitis C virus shares amino acid sequence similarity with pestiviruses and flaviviruses as well as members of two plant virus supergroups

Hepatitis C virus (HCV) is an important human pathogen that is associated with transfusion-related non-A, non-B hepatitis. Recently, HCV cDNA was cloned and the nucleotide sequence of approximately three-quarters of the virus genome was determined. A region of the predicted polyprotein sequence was found to share similarity with a nonstructural protein encoded by dengue virus, a member of the flavivirus family. We report here that HCV shares an even greater degree of protein sequence similarity with members of the pestivirus group (i.e., bovine viral diarrhea virus and hog cholera virus), which are thought to be distantly related to the flaviviruses. In addition, we find that HCV shares significant protein sequence similarity with the polyproteins encoded by members of the picornavirus-like and alphavirus-like plant virus supergroups. These data suggest that HCV may be evolutionarily related to both plant and animal viruses.

Molecular cloning and nucleotide sequence of the pestivirus bovine viral diarrhea virus

The RNA genome of the cytopathic NADL isolate of bovine viral diarrhea virus (BVDV) has been molecularly cloned and the nucleotide sequence determined. The cloned sequence was 12,573 nucleotides in length, corresponding to a molecular weight of 4.3 X 10(6), having a base composition of 32.2% A, 25.7% G, 22.1% U, and 20.0% C. However, the sequences at the 5' and 3' termini of the RNA have not been unequivocally established. A single major open reading frame extending the length of the molecule was found in the viral-sense (positive polarity) sequence. This open reading frame was capable of encoding 3988 amino acids, representing 449 kDa of protein.

Identification of a new group of bovine viral diarrhea virus strains associated with severe outbreaks and high mortalities

New BVDV strains associated with very high mortalities, which killed about 25% of the veal calves in Quebec in 1993, have been isolated. In this study, characterization of the last two-thirds of the 5' untranslated region (5'UTR) of their genome and virus neutralization experiments with polyvalent antisera raised in different animals both demonstrated that these strains formed a distinct group. Despite a difference of about 25% in the 5'UTR sequence with that of the classical strains, these 5'UTRs maintained the same secondary structure albeit with a higher stability. Serological crossreactivity between the classical and new BVDV strains was relatively low and suggest that new strains should also be included to obtain efficient BVDV vaccines. Based upon the distinct characteristics of these new BVDV strains, we propose to divide BVDV into two groups. Group I comprises the classical BVDV isolates including commonly used laboratory and vaccine strains, and group II comprises the newly described BVDV strains and those associated with thrombocytopenia and hemorrhaging.

Secondary structure of the 5' nontranslated regions of hepatitis C virus and pestivirus genomic RNAs

The RNA genomes of human hepatitis C virus (HCV) and the animal pestiviruses responsible for bovine viral diarrhea (BVDV) and hog cholera (HChV) have relatively lengthy 5' nontranslated regions (5'NTRs) sharing short segments of conserved primary nucleotide sequence. The functions of these 5'NTRs are poorly understood. By comparative sequence analysis and thermodynamic modeling of the 5'NTRs of multiple BVDV and HChV strains, we developed models of the secondary structures of these RNAs. These pestiviral 5'NTRs are highly conserved structurally, despite substantial differences in their primary nucleotide sequences. The assignment of similar structures to conserved segments of primary nucleotide sequence present in the 5'NTR of HCV resulted in a model of the secondary structure of the HCV 5'NTR which was refined by determining sites at which synthetic HCV RNA was cleaved by double- and single-strand specific RNases. These studies indicate the existence of a large conserved stem-loop structure within the 3' 200 bases of the 5'NTRs of both HCV and pestiviruses which corresponds to the ribosomal landing pad (internal ribosomal entry site) of HCV. This structure shows little relatedness to the ribosomal landing pad of hepatitis A virus, suggesting that these functionally similar structures may have evolved independently.

Processing of the envelope glycoproteins of pestiviruses

The genomic RNA of pestiviruses is translated into a large polyprotein that is cleaved into a number of proteins. The structural proteins are N terminal in this polyprotein and include three glycoproteins called E0, E1, and E2 on the basis of the order in which they appear in the polyprotein. Using pulse-chase experiments, we show that a pestiviral glycoprotein precursor, E012, is formed that is processed into E0, E1, and E2 in an ordered fashion. Processing is initiated by a nascent cleavage between the capsid and the translocated E012 followed by cleavage at the C terminus of E2. E012 is then rapidly cleaved to form E01 and E2. After E2 is released from the precursor, E01 is processed into E0 and E1. To identify the sites of cleavage, the N termini of the glycoproteins of the pestivirus classical swine fever virus (formerly termed hog cholera virus) were sequenced after expression in the vaccinia virus system. The N termini are Glu-268 for E0 (gp44/48), Leu-495 for E1 (gp33) and Arg-690 for E2 (gp55). The sequences around the cleavage sites capsid/E0 and E1/E2 conform to the rules known for cellular signal proteases, as does the sequence at the presumed C terminus of E2. The sequence upstream of the E0/E1 cleavage site also shows sequence characteristics of signalase processing sites but lacks the typical hydrophobic signal peptide; this cleavage site has characteristics in common with a site in flaviviruses that is also cleaved in a delayed fashion. The absence of any membrane-spanning region results in the shedding of E0 by infected cells, and E0 can be detected in the virus-free supernatant. Comparison of the sequences around the cleavage sites of pestiviruses suggests a general processing scheme for the structural glycoproteins. Comparison of the pesti- and flaviviral structural glycoproteins suggests analogies between E012 and prM-E.

Genetic and antigenic characterization of novel pestivirus genotypes: implications for classification

Currently, the genus Pestivirus comprises the four approved species Bovine viral diarrhea virus 1 (BVDV-1), BVDV-2, Classical swine fever virus (CSFV), and Border disease virus (BDV) and one tentative fifth species represented by a single strain (H138) isolated from a giraffe in Kenya more than 30 years ago. To further address the issue of heterogeneity of pestiviruses we have determined the entire N(pro) and E2 coding sequences for several new pestivirus isolates. Interestingly, phylogenetic analysis revealed that one pestivirus isolated in the 1990s in Africa is closely related to strain H138. Moreover, several novel pestiviruses isolated from sheep group together with the previously described strain V60 (Reindeer-1) isolated from a reindeer, whereas one ovine pestivirus strain (Gifhorn) significantly differs from all previously described pestiviruses, including BDV. We propose to term these mainly sheep-derived pestiviruses BDV-2 (V60-like isolates) and BDV-3 (Gifhorn); consequently, the "classical" BDV isolates should be termed BDV-1. As an additional criterion for segregation of pestiviruses, the antigenic relatedness of pestivirus isolates covering all observed major genotypes was studied by cross-neutralization assays. Analysis of the antigenic similarities indicated the presence of seven major antigenic groups corresponding to BVDV-1, BVDV-2, CSFV, BDV-1, BDV-2, BDV-3, and "giraffe". Taking into account the host origin, the lack of differences concerning the course of disease, and the results of our genetic and antigenic analyses, we suggest that BDV-1, BDV-2, and BDV-3 should be considered as major genotypes within the species BDV.

Phylogenetic analysis of pestiviruses from domestic and wild ruminants

Infections with pestiviruses occur in cattle, sheep, pigs and also in numerous other ungulate species. In the present study, pestiviruses from goat, buffalo, deer and giraffe were analysed at the molecular level; unusual strains from cattle and pigs were also included. A phylogenetic analysis of the respective pestiviruses was undertaken on the basis of a fragment from the 5' noncoding region as well as the gene encoding autoprotease Npro. Statistical analyses of the respective phylogenetic trees-based on the 5' NCR revealed low confidence levels for most of the branches, while the structure of the tree based on the Npro gene was supported by high bootstrap values. Accordingly, the isolates from goat, buffalo and deer can be grouped together with bovine viral diarrhoea virus (pestivirus type 1); within this genotype three subgroups and one disparate virus have been identified. One isolate from pig and one from cattle belong to the group of 'true' border disease virus (pestivirus type 3), which can be further subdivided into two major subgroups. Interestingly, the giraffe isolate does not belong to one of the four established pestivirus genotypes. The phylogenetic analysis strongly suggests that genotype 1 pestiviruses occur world-wide in many ruminant species. Furthermore, phylogenetic trees based on the Npro gene nucleotide sequences show that the respective sequences do not segregate into discrete lineages based on host-species origin.

Detection of a trypsin-like serine protease domain in flaviviruses and pestiviruses

We propose through a sequence and structural-pattern analysis that a protein domain of undefined function encoded by the enveloped RNA flavi- and pestivruses is a Ser active-center enzyme related to the cellular trypsin family. A further homology is emphasized with the group of (Cys active-center) viral proteases encoded by nonenveloped RNA viruses of the picorna-, como-, nepo-, and potyvirus classes. Structural modeling of the putative flaviviral protease domain suggests amino acids that are crucial for catalytic activity and substrate binding.

Proteins encoded by bovine viral diarrhea virus: the genomic organization of a pestivirus

The genome of bovine viral diarrhea virus (BVDV) contains a single large open reading frame capable of encoding 449 kDa of protein. Short segments from along the length of the molecularly cloned BVDV genome were engineered so as to be expressed as bacterial fusion polypeptides in Escherichia coli. These BVDV analog fusion proteins were used as immunogens to generate a panel of sequence-specific antisera. These antiserum reagents were in turn employed in immunoprecipitation analyses to identify the authentic BVDV protein to which they were directed. The results allowed for the identification and positioning along the genome of BVDV gene products accounting for approximately 83% of the coding capacity of the virus. A preliminary map of the genetic organization of BVDV is presented and discussed.

N-terminal domains of putative helicases of flavi- and pestiviruses may be serine proteases

Recently we tentatively identified, by sequence comparison, central domains of the NS3 proteins of flaviviruses and the respective portion of the pestivirus polyprotein as RNA helicases (A.E.G. et al., submitted). Alignment of the N-proximal domains of the same proteins revealed conservation of short sequence stretches resembling those around the catalytic Ser, His and Asp residues of chymotrypsin-like proteases. A statistically significant similarity has been detected between the sequences of these domains and those of the C-terminal serine protease domains of alphavirus capsid proteins. It is suggested that flavivirus NS3 and the respective pestivirus protein contain at least two functional domains, the N-proximal protease and the C-proximal helicase one. The protease domain is probably involved in the processing of viral non-structural proteins.

Genetic and antigenic characterization of an atypical pestivirus isolate, a putative member of a novel pestivirus species

The genus Pestivirus within the family Flaviviridae currently consists of four different main species: Classical swine fever virus, Bovine viral diarrhea virus types 1 and 2 and Border disease virus. A fifth tentative species is represented by an isolate from a giraffe. In this study, a completely new pestivirus, isolated from a batch of fetal calf serum that was collected in Brazil, is described. It is proposed that the isolate D32/00_'HoBi' may constitute a novel sixth pestivirus species, because it is genetically, as well as antigenically, markedly different from all other pestiviruses. Based on the entire N(pro)- and E2-encoding sequences, identities of <70 % to all other pestivirus species were determined. Similarly, cross-neutralization and binding studies using antisera and mAbs revealed marked antigenic differences between D32/00_'HoBi' and all other pestiviruses.

Molecular cloning and nucleotide sequence of hog cholera virus strain Brescia and mapping of the genomic region encoding envelope protein E1

Genomic RNA of hog cholera virus (HCV) strain Brescia was cloned and sequenced. The nucleotide sequence was deduced from overlapping cDNA clones and comprises 12,283 nucleotides. We cloned the complete 3' end of the HCV genome, but could not unequivocally prove that the cDNA sequence also completely covers HCV RNA at the 5' end. The HCV genome contained one large open reading frame, which spans the viral plus strand RNA and encodes an amino acid sequence of 3898 residues with a calculated molecular weight of 438,300. To identify structural HCV glycoproteins, we prepared rabbit antisera against three synthetic peptides deduced from the sequence. Because one of these antisera reacted with a 51- to 54-kDa glycoprotein (envelope protein E1 of HCV) on Western blot, the genomic position of the sequence encoding gp51-54 could be clearly established. The amino acid sequence of Brescia was compared with that of HCV strain Alfort and that of BVDV strains NADL and Osloss. The degree of homology between the two HCV strains was 93%, and between Brescia and the BVDV strains about 70%. NADL contained an inserted sequence of 90 amino acids that was absent from the sequences of Brescia, Alfort, and Osloss, whereas Osloss contained an inserted sequence of 76 amino acids that was absent from the sequences of Brescia, Alfort, and NADL. Sequences in p80, the most homologous protein among pestiviruses, showed similarity to six sequence motifs found conserved in helicase-like proteins represented by eIF-4A. Furthermore, a trypsin-like serine protease domain detected in p80 of BVDV was also found conserved in HCV, suggesting that pestivirus p80 may be bifunctional.

Molecular cloning and nucleotide sequence of a pestivirus genome, noncytopathic bovine viral diarrhea virus strain SD-1

Genomic RNA of noncytopathic (NCP) bovine viral diarrhea virus (BVDV) strain SD-1 was extracted directly from serum obtained from a persistently infected animal. cDNA was synthesized and amplified by polymerase chain reaction (PCR) before cloning. The complete genomic nucleotide sequence was determined by sequencing at least two different clones from independent PCR reactions. The 5' and 3' end sequences of the SD-1 genome was determined from 5'-3' ligation clones. The complete genome sequence was comprised of 12,308 nucleotides containing one large open reading frame which encodes an amino acid sequence of 3898 residues with a calculated molecular weight of 438 kDa. In contrast to cytopathic (CP) BVDV strain NADL, which contains a cellular RNA insert of 270 nucleotides and CP BVDV strain Osloss, which has an inserted ubiquitin RNA sequence of 228 nucleotides, the NCP strain SD-1 had no insertion along the genome. Sequence comparison with other pestiviruses revealed that the overall nucleotide sequence homologies of SD-1 are 88.6% with NADL, 78.3% with Osloss, 67.1% with HoCV Alfort, and 67.2% with HoCV Brescia. The overall deduced amino acid sequence homologies of SD-1 are 92.7% with NADL, 86.2% with Osloss, 72.5% with HoCV Alfort, and 71.2% with HoCV Brescia. The most conserved nucleotide and amino acid sequences are located in the 5' untranslated region (5'UTR) and nonstructural protein p80 region, respectively. The viral glycoproteins, particularly gp53, and nonstructural proteins p54 and p58 have the lowest homology comparing both nucleotide and amino acid sequences between SD-1 and other pestiviruses. Extensive analyses of amino acid sequences for the viral structural proteins and nonstructural protein p54 regions from five pestiviruses led to the identification of four conserved domains (designated as C1, C2, C3, C4) and three highly variable domains (designated as V1, V2, V3) within this region. The C1, C2, and C3 domains are located in the capsid protein p14, glycoprotein gp48, and gp25, respectively. The C4 domain is located in the junction between gp53 and p54. Interestingly, out of three variable domains, two (V1, V2) are located in the same glycoprotein gp53. The third variable domain is located in the nonstructural protein p54.

Genetic diversity of pestiviruses: identification of novel groups and implications for classification

The complete Npro coding sequences were determined for 16 pestiviruses isolated from cattle, pig, and several wild ruminant species including reindeer, bison, deer, and bongo. Phylogenetic analysis enabled the segregation of pestiviruses into the established species bovine viral diarrhea virus-1 (BVDV-1), BVDV-2, border disease virus (BDV), and classical swine fever virus (CSFV). For BVDV-1 five distinct subgroups were identified, while BVDV-2, BDV, and CSFV were each subdivided into two subgroups. The virus isolates from bongo and deer as well as one porcine virus isolate belong to BVDV-1. Interestingly, the isolates from reindeer and bison are distinct from the established pestivirus species. The Npro sequences from these two viruses are more similar to BDV than to the other pestivirus species. Calculation of the pairwise evolutionary distances allowed a clear separation of the categories species, subgroup, and isolate only when the reindeer/bison viruses were considered as members of an additional pestivirus species. Furthermore, the entire E2 coding sequences of a representative set of virus isolates covering all recognized species and subgroups were studied. Segregation of pestiviruses based on the E2 region was identical with that obtained with the N(pro) sequences.

Comparisons of the pestivirus bovine viral diarrhoea virus with members of the flaviviridae

The molecular features of bovine viral diarrhoea virus (BVDV), a member of the Pestivirus genus currently classified in the Togaviridae, were examined for characteristics resembling those of the Flaviviridae family. Like flaviviruses, BVDV possesses a single-stranded RNA genome (approx. 4.3 x 10(6) Mr) deficient in a 3' poly(A) tract. This RNA has a single open reading frame spanning the length of the genome in the viral RNA sense (positive polarity), implying an expression strategy involving the processing of a precursor polyprotein. With the exception of several short but significant stretches of identical amino acids within two non-structural proteins, no extended regions of nucleotide or amino acid sequence homology between BVDV and representatives of three serological subgroups of mosquito-borne flaviviruses were noted. However, comparison of the organization of protein-coding domains along the genomes and the hydropathic profiles of amino acid sequences revealed pronounced similarities. It is proposed that Pestivirus, of which BVDV is the prototype member, should no longer be grouped in the Togaviridae family, but rather be considered a genus of non-arthropod-borne viruses within the Flaviviridae.

An avirulent chimeric Pestivirus with altered cell tropism protects pigs against lethal infection with classical swine fever virus

A chimeric Pestivirus was constructed using an infectious cDNA clone of bovine viral diarrhea virus (BVDV) [J. Virol. 70 (1996) 8606]. After deletion of the envelope protein E2-encoding region, the respective sequence of classical swine fever virus (CSFV) strain Alfort 187 was inserted in-frame resulting in plasmid pA/CP7_E2alf. After transfection of in vitro-transcribed CP7_E2alf RNA, autonomous replication of chimeric RNA in bovine and porcine cell cultures was observed. Efficient growth of chimeric CP7_E2alf virus, however, could only be demonstrated on porcine cells, and in contrast to the parental BVDV strain CP7, CP7_E2alf only inefficiently infected and propagated in bovine cells. The virulence, immunogenicity, and "marker vaccine" properties of the generated chimeric CP7_E2alf virus were determined in an animal experiment using 27 pigs. After intramuscular inoculation of 1 x 10(7) TCID(50), CP7_E2alf proved to be completely avirulent, and neither viremia nor virus transmission to contact animals was observed; however, CSFV-specific neutralizing antibodies were detected from day 11 after inoculation. In addition, sera from all animals reacted positive in an E2-specific CSFV-antibody ELISA, but were negative for CSFV-E(RNS)-specific antibodies as determined with a CSFV marker ELISA. After challenge infection with highly virulent CSFV strain Eystrup, pigs immunized with CP7_E2alf were fully protected against clinical signs of CSFV infection, viremia, and shedding of challenge virus, and almost all animals scored positive in a CSFV marker ELISA. From our results, we conclude that chimeric CP7_E2alf may not only serve as a tool for a better understanding of Pestivirus attachment, entry, and assembly, but also represents an innocuous and efficacious modified live CSFV "marker vaccine".

Identification of a novel virus in pigs--Bungowannah virus: a possible new species of pestivirus

In 2003 an outbreak of sudden deaths occurred in 3-4-week-old piglets on a farm in New South Wales, Australia. There was a marked increase in the birth of stillborn foetuses. Pathological changes consisted of a multifocal non-suppurative myocarditis. A viral infection was suspected but a wide range of known agents were excluded. A modified sequence independent single primer amplification (SISPA) method was used to identify a novel virus associated with this outbreak. Conserved 5'UTR motifs, the presence of a putative N(pro) coding region and limited antigenic cross-reactivity with other members of the Pestivirus genus, support the placement of this virus in the Pestivirus genus. Phylogenetic analysis of the 5'UTR, N(pro) and E2 coding regions showed this virus to be the most divergent pestivirus identified to date.

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.

Molecular characterization of ovine pestiviruses

Forty-two ovine pestivirus isolates, collected over a period of 18 years, were compared by phylogenetic analysis. The viruses were mostly field isolates from Britain; two others originated from Sweden and two from New Zealand. RT-PCR products were obtained from two genomic regions, one within the 5'-noncoding (5'-NC) region, and the other encompassing parts of the p20 (Npro) and C coding regions. Direct sequencing of the 5'-NC PCR products, followed by computer-assisted phylogenetic analysis, divided the ovine pestiviruses into three main genotypes. The results demonstrated that sheep may naturally be infected not only with border disease virus (BDV), but also with bovine viral diarrhoea virus (BVDV) types I and II. The BDV isolates segregated into two principal subtypes represented by the Moredun strain from Scotland and the 137/4 strain from England. The BVDV-I group was composed of three clusters, two of them represented by BVDV reference strains NADL and Osloss, respectively, and the third by ovine isolates D1120/1 and D1432/P. The grouping of ovine pestiviruses, based on comparative nucleotide sequence analysis of the 5'-NC region, was confirmed by comparative analysis of the p20 (Npro) and C coding regions, performed both at the nucleotide and at the amino acid level. The presence of three genotypes in sheep, including BVDV-I and BVDV-II, indicates the inadequacy of the current hostspecies-based nomenclature and classification of pestiviruses.

5' and 3' untranslated regions of pestivirus genome: primary and secondary structure analyses

Within the conserved 5' untranslated region (UTR) of the pestivirus genome three highly variable regions were identified. Preceding the polyprotein start codon, multiple cryptic AUG codons and several small open reading frames are characteristic for all the five pestiviruses. Inspection of the context of AUGs revealed that the polyprotein initiation AUG of pestivirus has a weak context for efficient translation initiation. The most favorable context was found in two of the cryptic AUGs. Two oligopyrimidine-rich tracts upstream to the conserved either cryptic or authentic AUG in the 5'-UTR of pestivirus were identified and 83.3% of their nucleotide sequences are complementary to the consensus sequence at the 3' terminus of eucaryotic 18S rRNA. A secondary structure model for the 5'-UTR of pestivirus was predicted. Nucleotide sequence comparison among five pestiviruses led to the identification of a variable region and a conserved region in the 3'-UTR. A deletion of 41 nucleotides was found within the variable region in Osloss. A secondary structure model for the 3'-UTR was also predicted. The structural similarity of the 5'-UTR between pestiviruses and picornaviruses and hepatitis C viruses was demonstrated and the possible implications of features of the 5' and 3'-UTR of pestiviruses are discussed.

Identification of a Divergent Lineage Porcine Pestivirus in Nursing Piglets with Congenital Tremors and Reproduction of Disease following Experimental Inoculation

Congenital tremors is a sporadic disease of neonatal pigs characterized by action-related repetitive myoclonus. A majority of outbreaks of congenital tremors have been attributed to an unidentified virus. The objectives of this project were to 1) detect potential pathogen(s) in samples from piglets with congenital tremors and 2) develop an infection model to reproduce disease. Using next-generation sequencing, a divergent lineage pestivirus was detected in piglets with congenital tremors. The virus was originally most closely related to a bat pestivirus but is now more closely related to a recently published novel porcine pestivirus provisionally named atypical porcine pestivirus. A quantitative real-time PCR detected the virus in samples from neonatal piglets with congenital tremors from two separate farms, but not in samples from unaffected piglets from the same farm. To fulfill the second objective, pregnant sows were inoculated with either serum containing the pestivirus or PBS (control) by intravenous and intranasal routes simultaneously with direct inoculation of fetal amniotic vesicles by ultrasound-guided surgical technique. Inoculations were performed at either 45 or 62 days of gestation. All sows inoculated with the novel pestivirus farrowed piglets affected with congenital tremors while PBS-inoculated control piglets were unaffected. Tremor severity for each piglet was scored from videos taken 0, 1 and 2 days post-farrowing. Tremor severity remained relatively constant from 0 to 2 days post-farrowing for a majority of piglets. The prevalence of congenital tremors in pestivirus-inoculated litters ranged from 57% (4 out of 7 affected piglets) to 100% (10 out of 10 affected piglets). The virus was consistently detected by PCR in tissues from piglets with congenital tremors but was not detected in control piglets. Samples positive by PCR in greater than 90% of piglets sampled included brainstem (37 out of 41), mesenteric lymph node (37 out of 41), tracheobronchial lymph node (37 out of 41), and whole blood (19 out of 20). Although the first description of congenital tremors was in 1922, this is the first reported reproduction of congenital tremors following experimental inoculation with a divergent lineage porcine pestivirus. Studies investigating disease mechanism, epidemiology, and diagnostic assay development are needed to better understand the pathophysiology of congenital tremors due to this pestivirus.