Sequence analysis of infectious pancreatic necrosis virus genome segment B and its encoded VP1 protein: a putative RNA-dependent RNA polymerase lacking the Gly-Asp-Asp motif

The genome segment B sequence of infectious pancreatic necrosis virus was determined for both the Jasper and Sp serotypes. The sequences are 2784 and 2630 bp long, respectively, and contain a single large open reading frame encoding the VP1 protein, the putative RNA-dependent RNA polymerase (RdRp) of IPNV. The proteins exhibit an 88% homology with each other, but only 41% with infectious bursal disease virus (IBDV) VP1, another member of the Birnaviridae. Despite the low overall homology between the IPNV and IBDV VP1 proteins, homologous regions were detected within the central portion of the proteins. The carboxy-proximal regions of the VP1, which contain very low amino acid homology, displayed evidence of conservation in structural features such as a hydrophilic, highly basic domain. Consensus sequences associated with GTP-binding proteins and RdRps were also detected in VP1. However, unlike the RdRps associated with single-stranded plus RNA viruses, the birnavirus RdRp lacks the Gly-Asp-Asp motif characteristic of this enzyme family.     

Evolutionary relatedness of the predicted gene product of RNA segment 2 of the tick-borne Dhori virus and the PB1 polymerase gene of influenza viruses

The complete nucleotide sequence of the second largest RNA segment of Dhori/India/1313/61 virus was determined and the deduced amino acid sequence was compared with the polymerase (P) proteins of influenza A, B, and C viruses. RNA segment 2 (2224 nucleotides) of Dhori virus contains a single long open reading frame that can encode a 716-amino acid polypeptide (81.3 kDa). The predicted polypeptide shares between 27 and 31% sequence identities with the PB1 polypeptides of influenza A, B, and C viruses. Among the regions most highly conserved are the sequences around the Asp-Asp motif common to many RNA polymerases. In spite of the high level of sequence identity between the Dhori RNA segment 2 gene product and the influenza A, B, and C virus PB1 proteins the amino acid composition of the Dhori protein indicates an acidic charge feature at pH 7.0 in contrast to the basic nature of the PB1 proteins of the influenza viruses. We suggest that the Dhori PB1-like protein be designated the P alpha protein of this virus.     

The genome segment B encoding the RNA-dependent RNA polymerase protein VP1 of very virulent infectious bursal disease virus (IBDV) is phylogenetically distinct from that of all other IBDV strains

A full-length cDNA clone of the segment B of the very virulent infectious bursal disease virus (IBDV) strain BD 3/99 was constructed and the full-length nucleotide sequence was established. The nucleotide sequence encoding VP1, an RNA-dependent RNA polymerase, of BD 3/99 was aligned with that of 17 other IBDV strains including six very virulent, three classical virulent, five classical attenuated, one antigenic variant and two serotype 2 strains. The VP1 genes of all very virulent strains were 97.5% to 99.8% identical. With the exception of an atypical Australian strain, 002-73, all of the classical virulent or attenuated and antigenic variant strains were also 97.5% to 100% identical. Serotype 2 strains showed only 4-6% divergence from serotype 1 classical virulent or attenuated strains; in contrast, however, the very virulent strains were 10.5% to 12.5% divergent from the classical virulent or attenuated strains as well as serotype 2 strains. Analysis of the deduced amino acid sequence of VP1 revealed 17 common, including 8 unique amino acid substitutions in the very virulent strains. In the phylogenetic tree the very virulent strains formed a distinct cluster and all other strains including classical virulent, attenuated and antigenic variant strains and even serotype 2 strains were grouped together. It is suggested that the VP1 of very virulent IBDV is phylogenetically distinct from that of all other IBDV strains and probably originated from a hitherto unidentified source.     

Mapping of cross-reacting and serotype-specific epitopes on the VP3 structural protein of the infectious bursal disease virus (IBDV)

Summary The binding sites of a panel of monoclonal antibodies cross-reacting with the structural protein VP3 of the two serotypes of the infectious bursal disease virus (IBDV) could be mapped to four segments of the VP3 gene. Two of these antigenic domains also carry epitopes which are specific for one serotype only. Formation of the common or type-specific epitopes is in agreement with homologous or mismatching amino acid sequences yielding hydrophilic segments on the VP3 polypeptide. These antigenic patterns obtained by immunoblotting could be verified by a competitive ELISA.     

Full-length sequence analysis of four IBDV strains with different pathogenicities

Characterization of field isolate 9109, Lukert, Edgar cell culture-adapted (CCA), and Edgar chicken embryo-adapted (CEA) serotype 1 IBDV strains using full-length genomic sequences is reported. IBDV genomic segments A and B were sequenced and the nucleotide and deduced amino acid (aa) sequences were compared with previously reported full-length sequenced IBDV strains. We found that the viral protein VPX and amino acid sequences between aa 202-451 and 210-473 of VP2 but not the entire VP2 protein are the best representatives of the entire IBDV genome. The greatest variability was found in the VP2 and 5' non-coding region of segment B among IBDV strains. The deduced amino acid sequences of the VP1 protein varies in length among the strains analyzed. The RNA-dependent, RNA-polymerase motifs within VP1 and the VP5 protein were highly conserved among isolates. Although within the VP2 processing site, amino acid sequence of Lukert was similar to the classical while the Edgar CCA, and CEA were more similar to the very virulent strains, it was determined that these strains have sequence characteristics of the classical strains. In addition, close relatedness between Lukert, Edgar CCA and CEA was observed. Although phylogenetic analysis of the VP1, VP3, and VP4 proteins indicated that 9109 is a classical type virus, this isolate shares unique amino acid changes with very virulent strains within the same proteins. Phylogenetic analysis of the 3' and 5' non-coding regions of segment A revealed that 9109 is more similar to the very virulent strains compared to the classical strains. In the VP2 protein, several amino acids were conserved between variant E and 9109 strains. Thus, it appears that 9109 isolate has characteristics of classical, very virulent, and variant strains. Our analysis indicates that although VPX amino acid comparison may be initially useful for molecular typing, full-length genomic sequence analysis is essential for thorough molecular characterization as partial sequences may not designate a particular strain as very virulent, classical, or variant.     

Sequence and phylogenetic analyses of highly virulent infectious bursal disease virus

Summary.  The nucleotide sequences of the genome segment A and B encoding the precursor polyprotein (NH₂-VP2-VP4-VP3-COOH) and VP1 were determined for a highly virulent strain of infectious bursal disease virus (IBDV). The precursor polyprotein and VP1 coding regions of highly virulent OKYM strain consisted of 3 039 nucleotides (1 012 deduced amino acids) and 2 640 nucleotides (879 deduced amino acids), respectively. Comparison of the deduced amino acid sequences of the highly virulent IBDV (HV-IBDV) with other serotype 1 and 2 sequences revealed 17 amino acid residues which were conserved only in the HV-IBDV. Among the 17 unique amino acid differences, 8 were in VP1, 4 were in VP2, 3 were in VP3 and 2 were in VP4. Although it is impossible to predict the effect of the unique amino acid residues without detailed knowledge of the three-dimensional structure and function of the proteins, they could affect the virulence of HV-IBDV. Alignment of the nucleic acid sequences of precursor polyprotein, VP1, VP2, VP3 and VP4 coding regions followed by distance analysis allowed the generation of phylogenetic trees. The same tree topology was obtained for the nucleotide sequence of precursor polyprotein, VP2, VP3 and VP4. On the other hand, the tree topology of VP1 was quite different from that obtained for the nucleotide sequence of precursor polyprotein, VP2, VP3 and VP4. These findings indicate that not a genetic recombination but a genetic reassortment may play an important role in the emergence of HV-IBDV. Accepted January 16, 1997; Received October 25, 1996     

Nucleotide sequence and phylogenetic analysis of a segment of a highly virulent strain of infectious bursal disease virus

The complete nucleotide sequences encoding precursor polyprotein (VP2-VP3-VP4) and VP5 of a highly virulent (hv) infectious bursal disease virus (IBDV), UPM97/61 was determined. Comparison of the deduced amino acid sequences with the published ones revealed 8 common amino acid substitutions, which were found only in the hv IBDV including the UPM97/61 strain. Three of the amino acid substitutions (222 Ala, 256 Ile and 294 Ile) were used as a marker for determining hv IBDV strains. The other five substitutions (685 Asn, 715 Ser, 751 Asp, 990 Val and 1005 Ala) were also conserved in hv IBDV strains isolated in various countries. UPM97/61 strain demonstrated also 8 unique amino acid substitutions of which 3 were in VP2, 4 in VP3 and 1 in VP4. There was 1 unique amino acid substitution in VP5 at position 19 (Asp-->Gly) not found in other strains. However, all the strains have a conserved 49 Arg. The amino acid sequence of UPM97/61 strain differed by 1.09% from the Japanese (OKYM) and Hong Kong (HK46) strains, and by 1.48% from the Israeli (IBDVKS) and European (UK661) strains. Hence, UPM97/61 is more closely related to the hv strains from Asia. However, phylogenetic analysis indicated that the origin of UPM97/61 might be the same as that of other hv strains isolated from other parts of the world.     

Evidence that virion-associated VP1 of avibirnaviruses contains viral RNA sequences

Summary.  The VP1 encoded by genomic segment B of birnaviruses is generally known to exist as a genome-linked protein (VPg) and as a “free” polypeptide of 90 kDa in virus particles. The guanylylation activity associated with infectious bursal disease virus (IBDV) was demonstrated by incubating purified virus in presence of [] GTP; optimum activity in the 90 kDa form of VP1 was seen in low salt concentration in the presence of 4 mM magnesium ions over a wide range of incubation temperatures. The IBDV VP1 was shown to lack guanyl transferase activity. Northwestern (RNA-protein) blot analysis of purified virus using a radiolabeled cDNA probe consisting of and ends of genomic segment B indicated that both forms of virion-associated VP1 contained viral RNA sequences of which those linked to VPg corresponded to the two genome segments and those linked to the 90 kDa VP1 were probably a short oligonucleotide of the terminal viral RNA sequences. Received August 23, 1996 Accepted October 29, 1996     

Molecular characteristic of VP2 gene of infectious bursal disease viruses isolated from a farm in two decades

Infectious bursal disease virus (IBDV) is a double-stranded RNA virus in the Birnaviridae family. Four pathotypes, attenuated, virulent, antigenic variant, and very virulent, have been identified. In this study, we examined the phylogenetic relationship of 25 field isolates that were collected from a single farm during 1989–2008. A sequence analysis of PCR amplified 714 bp VP2 region showed that all the samples were derived from very virulent infectious bursal disease virus (vvIBDV) and were more closely related to the vvIBDV isolate UK661. From 1999, the isolate XA1999 had amino acids I228 and T394. XA2000, XA2001, XA2002, and XA2003-09 had amino acids E279 and T394. From 2004 to 2008, the isolates had amino acids H320, I349, S375, and R381 while the UK661 virus had T228, D279, Q320, V349, P375, K381, and A394. Such mutations do not change key amino acid residues in the domains which are essential for its virulence. It suggests that a virulent IBDV strain could maintain its virulence for a long period in the same chicken farm and the strain is highly stable under normal environments.     

Studies on naturally occurring infectious bursal disease viruses suggest that a single amino acid substitution at position 253 in VP2 increases pathogenicity

Three classic IBDV strains were previously isolated from commercial layer chicken flocks and shown to be phylogenetically related to vaccine strains but pathogenic in susceptible chickens. In this study, their viral genomes were sequenced and compared to sequences of vaccines being used in those flocks. The vaccine strains examined were sequenced directly from the manufacturer and had identical genome segment B sequences. Compared to these vaccines, the GA-1, H-30 and CS-2-35 isolates each had one silent mutation in the gene that encodes VP1. Compared to the two vaccines used at the time CS-2-35 was isolated, the segment A sequence of CS-2-35 contained numerous nucleotide and amino acid mutations suggesting the CS-2-35 virus was not closely related to these vaccines. This virus however did have amino acid mutations in VP2 that are reported to be necessary for replication in cell culture and lacked two of the three amino acid mutations previously shown to be necessary for virulence. These data suggest that CS-2-35 was a descendant from an attenuated strain of IBDV. When the segment A genomic sequences of the GA-1 and H-30 viruses were compared to the vaccines being used in those flocks they were most closely related to the attenuated D78 vaccine strain. In genome segment A, three nucleotide mutations in GA-1 and four in H-30 were observed compared to the D78 classic vaccine. These nucleotide mutations caused one amino acid (H253N) change in the GA-1 virus and two amino acids (H253Q and G259D) were different in the H-30 virus. In addition, both the GA-1 and H-30 viruses had the amino acid G76 in VP2 that appears to be unique to the vaccine D78. The data suggest that GA-1 and H-30 are genetically related and have a common ancestor even though they were isolated from geographically distant flocks. The evidence also suggests that GA-1, H-30 and CS-2-35 could be reversions from attenuated vaccine viruses or by coincidence genetically resemble classic IBDV vaccines. It should be noted that some of the classic virus vaccines were not being used according to the manufacturer's recommendations at the time the GA-1, H-30 and CS-2-35 strains were isolated. Together, the molecular and pathogenicity data indicate that a single amino acid mutation from Histidine (H) to Glutamine (Q) or Asparagine (N) at position 253 in VP2 will markedly increase the virulence of an attenuated IBDV.     

Genetic mechanisms of antigenic variation in infectious bursal disease virus: Analysis of a naturally occurring variant virus

The major immunogenic protein VP2 from a pathogenic field isolate (variant A virus) of infectious bursal disease virus (IBDV) was cloned and sequenced to examine antigenic variations. The VP2 open reading frame consists of 1509 nucleotides and codes for a 503 amino acid protein. Overall, the VP2 amino acid sequence of the variant A virus shares 98.6% identity with VP2 genes from other published IBDV strains. However, within the central region of VP2 (amino acids 222–334) lies a highly divergent area that we have termed thevariable domain. Relative to five other IBDV isolates, a total of six amino acid changes occur within the variable domain of the variant A virus. At positions 284–288, a substitution of isoleucine to threonine, a decrease in the number of Chou and Fasman turns, and a switch from a hydrophilic to a hydrophobic region are found only in the variant A virus. Together these changes predict a decrease in antigenicity as determined by calculation of potential antigenic sites. This suggests that only minor changes within VP2 contributed to the emergence of a variant virus that can cause disease in immunized birds.     

VP1, the RNA-dependent RNA polymerase and genome-linked protein of infectious bursal disease virus,interacts with the carboxy-terminal domain of translational eukaryotic initiation factor 4AII

Summary. Infectious bursal disease virus (IBDV), a member of the family Birnaviridae, is a non-enveloped, double-stranded RNA virus. Viral protein 1 (VP1), the putative RNA-dependent RNA polymerase, occurs in virions both as a free polypeptide and as a genome-linked protein, called VPg. To gain more insight in its function, we initiated a yeast two-hybrid screen. With this approach we identified the carboxy-terminal domain of eukaryotic translation initiation factor 4AII (eIF4AII) as an interactor for VP1. The association between these molecules was confirmed by co-immunoprecipitation analyses. eIF4A plays an essential role in the initiation of translation of both capped and uncapped mRNAs. Its association with IBDV VP1 suggests an involvement of this viral protein in IBDV mRNA translation. An interaction between VP1 and full-length eIF4AII was, however, not observed. In view of the known two-domain structure of eIF4AII it is conceivable that the interaction of VP1 with full-length eIF4AII requires collaborating proteins that open up its structure and expose the VP1-binding site in the carboxy-terminal domain. The biological relevance of the potential VP1-eIF4AII interaction is discussed.     

Complete nucleotide sequence of segment 5 of epizootic haemorrhagic disease virus; the outer capsid protein VP5 is homologous to the VP5 protein of bluetongue virus

The complete nucleotide sequence of a cDNA clone representing the segment 5 RNA of epizootic haemorrhagic disease virus (EHDV) United States serotype 1 was determined. The 5' and 3' termini of the RNA are complementary and are capable of forming secondary structures. The comparison of the predicted amino acid sequence of the encoded outer capsid protein (VP5) with the sequences of VP5 from four serotypes of bluetongue virus, the prototype orbivirus, revealed that the protein shares 59% to 62% homologies with various BTV serotypes, including a single conserved glycine residue at the amino terminus. The sequence has been submitted to the Genebank databox (X55782).     

Complete nucleotide sequence of the Japanese encephalitis virus genome RNA

The complete nucleotide sequence of the Japanese encephalitis virus (JEV) genome RNA was determined. The JEV genome contains 10,976 nucleotides and encodes a single long open reading frame (ORF) of 10,296 nucleotides corresponding to 3432 amino acid residues. This long polypeptide is thought to be cleaved into three structural proteins and several nonstructural proteins of the virus. The genetic location of the three structural proteins was determined by comparing the deduced amino acid sequence from the nucleotide sequence with the N-terminal amino acid sequences that were determined from the three purified structural proteins. The C-terminal region of the ORF may encode a RNA-dependent RNA polymerase which has significant sequence homology with those of other RNA viruses.     

Sequence variability and evolution of the terminal overlapping VP5 gene of the infectious bursal disease virus

The infectious bursal disease virus (IBDV; Birnaviridae family) constitutes one of the main threats to the poultry industry worldwide. Most of the progress in the molecular epidemiology of this virus has been achieved through the study of the coding region of the capsid protein VP2. Little research has been done regarding the molecular evolution and the epidemiological implications of genetic variability of other IBDV genome regions. In this article, the gene that codes the non-structural protein VP5 was analyzed. Although this protein is not essential for the virus replication, recent evidence indicates that it could be related to the virulent phenotype and the adaptive capacity of the virus. The VP5 gene is also of evolutionary interest because it has an open reading frame that terminally overlaps with the pVP2–VP4–VP3 polyprotein coding region. In the first part of this study, the full VP5 gene of a South American strain was characterized. The results revealed that the VP5 gene of Uruguayan hypervirulent IBDV strains (vvIBDV) lacks the alternative AUG start codon characteristic of the vvIBDV strains that have been described to date. Instead, as occurs in classic and variant strains, this VP5 gene has an AUG start site located four codons downstream and, consequently, it codes for a 145 amino acid long protein rather than the putative 149 amino acid long protein of other vvIBDV. In spite of this, these viruses conserved the VP5 and VP2 amino acid signature of the hypervirulent strains and clustered with reference vvIBDV sequences. This finding may represent evidence that the VP5 gene could be evolving by changing the translation initiation site. In the second part of this study, an evolutionary analysis including the sequences reported in this study together with most of VP5 sequences available in the GenBank, showed the existence of a complex system of selective pressures controlling the evolution of the VP5 gene. Using the dN/dS index, we found a strong purifying selection exerted on the 5′ terminal overlapping region of VP2 that would be constraining the evolution of VP5. These results reinforce the hypothesis that the VP5 gene was originated late in the IBDV evolution by a mechanism of genetic overprinting. The results described in this study provided new information about the dynamics of the IBDV genome and revealed some of the mechanisms at play in the evolution of this virus. Since VP5 seems to be related to viral pathogenicity, this evolutionary information might be useful to highlight the impact of the genetic variation of this protein on the epidemiology of IBDV.     

Cloning and Nucleotide Analysis of Segment A Gene of Infectious Bursal Disease Virus Detected in Korea

A strain of infectious bursal disease virus (IBDV) was detected from bursal tissues of chicks which suffered from infectious bursal disease (IBD) in Chinju, Korea and provisionally named as Chinju strain. A full-length cDNA clone for segment A gene of the virus was constructed, and complete nucleotide sequence of the gene including noncoding region was determined and analyzed by comparison with that of other IBDV strains. The segment A gene of Chinju strain consisted of 3,269 nucleotides including 862 adenine (26.4%), 917 cytosine (28.0%), 854 guanine (26.1%) and 636 thymine (19.5%). There were regions for two open reading frames (ORFs), ORF1 encoding the VP5 with ATG codon at nucleotides 98–100 and ORF2 encoding the polyprotein of VP2, VP4 and VP3 in the nucleotides 132–3,170. In deduced translation the ORF2 encoded 1,012 amino acids. The full nucleotide sequence of segment A gene and amino acid sequence of ORF2 of the Chinju strain showed 98–99% homology with those of the very virulent IBDVs (vvIBDVs) such as HK46, OKYM, UK661, UPM97/61, D6948 and BD3/99. In phylogenetic analysis of nucleotide and amino acid sequences, the Chinju strain was also related closely to the vvIBDVs. Hence, it was suggested that the Chinju strain is a vvIBDV. The nucleotide and amino acid sequences of the Chinju strain with pertinent information can be useful for the development of genetically engineered vaccines and diagnostic reagents against vvIBDV.     

Isolates of infectious bursal disease virus from India are of very virulent phenotype

Four Indian field isolates, a classical virulent and an attenuated vaccine strains of Infectious bursal disease virus (IBDV) have been characterized by sequence analysis of part of the VP1 gene (from nucleotide 1538-1979) comprising one of viral RNA dependent RNA polymerase motifs. Sequence alignment of these viruses with reported viruses of other countries revealed Indian IBDV field isolates to be 100% similar to very virulent Japanese (OKYM), European (UK661) and Bangladesh (BD3/99) IBD viruses at amino acid level, whereas they had 0.2-0.9% divergence at nucleotide level. Out of the total 24 nucleotide changes found in the Indian field isolates, as well as reported very virulent viruses, only one resulted in amino acid change S-P at 562 position. The Indian field isolates displayed nucleotide divergence of 10.6-11.6% and amino acid divergence of 2.8-3.5% from the classical virulent and attenuated vaccine strains. The RNA dependent RNA polymerase motif from amino acid 528-541, present in the sequence analyzed, was conserved among all the viruses, irrespective of pathotype and serotype. In the phylogenetic tree, based on nucleotide sequence, Indian field viruses were grouped with reported very virulent viruses in one lineage whereas, classical virulent, attenuated vaccine and serotype 2 strains formed part of the second lineage. But in the phylogenetic tree based on amino acid sequence alignment, the serotype 2 strain OH grouped with Indian field isolates and reported very virulent viruses in one lineage and classical virulent and attenuated vaccine strains formed the second lineage.