Eubenangee virus has previously been identified as the cause of Tammar sudden death syndrome (TSDS). Eubenangee virus (EUBV), Tilligery virus (TILV), Pata virus (PATAV) and Ngoupe virus (NGOV) are currently all classified within the Eubenangee virus species of the genus Orbivirus, family Reoviridae. Full genome sequencing confirmed that EUBV and TILV (both of which are from Australia) show high levels of aa sequence identity (>92%) in the conserved polymerase VP1(Pol), sub-core VP3(T2) and outer core VP7(T13) proteins, and are therefore appropriately classified within the same virus species. However, they show much lower amino acid (aa) identity levels in their larger outer-capsid protein VP2 (<53%), consistent with membership of two different serotypes - EUBV-1 and EUBV-2 (respectively). In contrast PATAV showed significantly lower levels of aa sequence identity with either EUBV or TILV (with <71% in VP1(Pol) and VP3(T2), and <57% aa identity in VP7(T13)) consistent with membership of a distinct virus species. A proposal has therefore been sent to the Reoviridae Study Group of ICTV to recognise ‘Pata virus’ as a new Orbivirus species, with the PATAV isolate as serotype 1 (PATAV-1). Amongst the other orbiviruses, PATAV shows closest relationships to Epizootic Haemorrhagic Disease virus (EHDV), with 80.7%, 72.4% and 66.9% aa identity in VP3(T2), VP1(Pol), and VP7(T13) respectively. Although Ngoupe virus was not available for these studies, like PATAV it was isolated in Central Africa, and therefore seems likely to also belong to the new species, possibly as a distinct ‘type’. The data presented will facilitate diagnostic assay design and the identification of additional isolates of these viruses.
Citation: Belaganahalli MN, Maan S, Maan NS, Nomikou K, Pritchard I, et al. (2012) Full Genome Sequencing and Genetic Characterization of Eubenangee Viruses Identify Pata Virus as a Distinct Species within the Genus Orbivirus. PLoS ONE 7(3): e31911. doi:10.1371/journal.pone.0031911
Editor: Herman Tse, The University of Hong Kong, Hong Kong
Received: December 8, 2011; Accepted: January 16, 2012; Published: March 15, 2012
Copyright: © 2012 Belaganahalli et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was partly funded by the Commonwealth Scholarship Commission (http://cscuk.dfid.gov.uk/) awarded to MB, partly by the Department for Environment, Food and Rural Affairs (Defra)(SE2617) awarded to SM, partly by the Wellcome BTV Programme grant (http://www.wellcome.ac.uk/) awarded to KN. NSM, PCM and HA were involved in this work, funded by the Biotechnology and Biological Sciences Research Council (BBSRC), the European Union (EU) (SANCO/940/2002) and Defra. IP and RL were part of this work, funded by CSIRO & Dept of Agriculture, Fisheries and Forestry, Australian Government. PK was funded by NSW Department of Primary Industries. No additional external funding received for this study. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Eubenangee virus (EUBV) is one of 22 species (which also represent distinct virus serogroups) of the genus Orbivirus within the family Reoviridae. The orbiviruses are vector borne, non-enveloped, icosahedral viruses, with genomes composed of 10 segments of linear dsRNA. Bluetongue virus (BTV) is the type species of the genus, which also contains 14 currently unclassified strains, some of which may represent additional species , , , , , . The orbiviruses are primarily transmitted by ticks or haematophagus-insect-vectors (including Culicoides, mosquitoes and sand flies) and have a wide host-range that collectively includes domestic and wild ruminants, equines, marsupials, sloths, bats, birds and humans , , .
The Eubenangee virus species/serogroup contains viruses that infect both marsupials and cattle, that have also been isolated from mosquitoes and Culicoides , . Four distinct Eubenangee viruses have been recognized: Eubenangee virus (EUBV); Tilligerry virus (TILV); Pata virus (PATAV); and Ngoupe virus (NGOV) . Eubenangee virus was first isolated in Australia in 1963 from a pool of 31 mosquitoes belonging to 11 species . It was also isolated from Culicoides spp. and antibodies to the virus have been detected in cattle and marsupials , . Tilligerry virus was isolated in 1971 from Anopheles annulipes mosquitoes in Australia  and is related to, but distinct from EUBV , . The morphology and morphogenesis of Tilligerry virus as examined by electron microscopy appear similar to those described for other orbiviruses .
Pata virus was isolated in 1968 from pool of Aedes palpalis mosquitoes in the Central African Republic . Ngoupe virus was isolated six years later in 1974 from Aedes tarsalis also in the Central African Republic . Unfortunately, Ngoupe virus is not available from the Orbivirus Reference Collection (ORC) at the Institute for Animal Health (IAH) and has not been included in this study.
The disease producing potential of EUBV was not widely explored until the virus was isolated in Australia between October 1998 and March 1999, from wallabies affected by the Tammar sudden death syndrome (TSDS) , , . The epizootic of TSDS was first noted in captive research colonies near Sydney, then at two zoological gardens in New South Wales and later at a research facility in Queensland . Some of the clinical signs of TSDS resemble peracute bluetongue, however the majority of affected animals died with no premonitory signs and showed accelerated autolysis within 12 hrs of death .
Another suspected outbreak of TSDS occurred in western Sydney in 2007 but no virus was isolated . In November 2010, sudden deaths of Tammar wallabies were again reported from several different locations in eastern Australia, with mortality rates as high as 75%, possibly related to the abundance of adult Culicoides in the region , . Gross post-mortem findings included widespread pulmonary congestion and haemorrhages throughout the body , . Eubenangee viruses and/or Wallal viruses were also implicated during 1998, in the sudden onset of subcutaneous edema, pruritis and urticarial lesions of the lower hind legs, tail and ears of captive red kangaroos from the Northern Territory of Australia . Although Eubenangee viruses were identified as etiological agents of TSDS by virus isolation and serological methods during 1998–1999, only partial sequence of VP3 (T2) were available in the database , however the full genome of Eubenangee virus has not previously been fully sequenced.
The similar host range, distribution, co-circulation and relatively close serological relationships between EUBV, BTV and EHDV, has occasionally made diagnosis and identification of specific etiological agents difficult by serological methods . However, full genome sequence analyses and phylogenetic comparisons of multiple orbivirus isolates from individual or closely related Orbivirus species have supported the development of faster and more reliable virus-species/serogroup/serotype specific diagnostic assays, by conventional and/or real-time RT-PCR , , , . These assays have supported molecular epidemiology studies and in some cases have helped to reassess the taxonomic classification of individual viruses , .
We report full genome sequence data for Eubenangee virus (EUBV), Pata virus (PATAV) and Tilligerry virus (TILV), which will facilitate development of relevant assays and identification of further isolates that belong to the species Eubenangee virus. These data also support the reclassification of PATAV as a distinct new Orbivirus species. A proposal to this effect has been sent to the Reoviridae Study Group of the International Committee on Taxonomy of Viruses (ICTV).
Virus propagation and genomic dsRNA electropherotype
EUBV, TILV and PATAV isolates (obtained from the Orbivirus Reference Collection (ORC) at IAH (http://www.reoviridae.org/dsRNA_virus_proteins/ReoID/Eubenangee-isolates.htm#EUBV)) induced characteristic cytopathic effects (CPE) in BHK and BSR cell monolayers, between 48–72 hours post infection. Purified dsRNAs of these viruses were analysed by 1% agarose gel electrophoresis (AGE), along with representative BTV and EHDV strains (Figure 1). In this system, EUBV and TILV generated almost identical genome segment migration patterns (Lane 3 and 4 in Figure 1), typical of viruses belonging to the same virus species , , while PATAV shows little but clear differences in the migration pattern of Seg-7, 8, 9 and 10 (Lane 5 in Figure 1). Seg-7 and 8 of the PATAV co-migrate, while those of EUBV and TILV migrate separately. Although these differences are small, they are comparable in magnitude to the differences between BTV-1w (LIB2007/07 - lane 1), EHDV-6w (USA2006/05 – lane 2), EHDV-8e (AUS1982/05 – lane 6) and EUBV (lane 3).
Lane M = 100 bp Marker; 1 = BTV-1w (LIB2007/07); 2 = EHDV-6w (USA2006/05); 3 = EUBV (AUS1963/01); 4 = TILV (AUS1978/03); 5 = PATAV (CAF1968/01); 6 = EHDV-8e (AUS1982/05).
Characterisation of the EUBV, TILV and PATAV genome segments
Accession numbers for sequences reported here include: EUBV genome segments JQ070376 to JQ070385; TILV genome segments JQ070366 to JQ070375; PATAV genome segments JQ070386 to JQ070395. The characteristics of the genome segments and encoded proteins are given in Table 1. The G+C content of the full genome of EUBV, TILV and PATAV is 44.99%, 45.143% and 42.2% respectively. The genomes of EUBV and TILV are 19304 bp and 19342 bp respectively, with segments ranging from 3962 to 856 bp, encoding proteins of 1307 to 242 aa length (Table 1). As already suggested (by Figure 1) half of the genome segments (Seg-1, 3, 4, 6 and 8) of EUBV and TILV have identical sizes, while all of the ORFs, except for VP2 and NS4 (Seg-2 and Seg-9), have identical start and stop positions relative to the upstream end, generating proteins of the same length (Table 1).
The overall size of PATAV genome is 19340 bp, with genome segments that range from 3948 bp to 851 bp, encoding proteins of 1303 aa to 237 aa length. All of the PATAV RNAs and ORFs (except for Seg-4) have different sizes and positions from those of EUBV and TILV, leading to the production of proteins with different sizes. The coding assignments of EUBV, TILV and PATAV genome segments are similar to those of BTV and the other Culicoides borne orbiviruses, with the exception of PATAV Seg-7 and 8, which have changed their relative order of size, compared to those of TILV and EUBV (Table 1).
The genome segments of all three viruses have shorter 5′ non coding regions (NCR) (9–28 bp in EUBV and TILV; 7–32 bp in PATAV) than 3′ NCRs (29–111 or 29–116 bp in EUBV or TILV; 28–120 bp in PATAV) with conserved terminal hexanucleotides that are comparable to, but in some cases not identical to those of BTV or EHDV (Table 2). Two nucleotides at the 5′ end and three nucleotides at the 3′ end are fully conserved (5′-GU……UAC-3′) while the first and last 2 nucleotides of each genome segment are also inverted complements, characteristics of the genus Orbivirus (http://www.reoviridae.org/dsRNA_virus_proteins/CPV-RNA-Termin.htm). These results confirm an early report of the conserved termini of Tilligerry virus genome segments (5′-GU–A………….AC-UAC-3′) as identified by enzymatic digestion and electrophoresis .
Most of the ORF's of the EUBV and TILV genome segments have a strong Kozak sequence (RNNATGG), except for the first ORFs of Seg-9 (CTGATGA) and Seg-10 (GC/ATATGT), both of which have a ‘weak’ context, but also encode additional smaller proteins from downstream initiation sites (generating NS4 and NS3a respectively). The ORF's of PATAV genome segments have the initiation sequence RNNATG, followed by ‘G’ in Seg-1,5,6,7,8 (strong Kozak context); ‘A’ in Seg-2, 3 (adequate Kozak context); ‘C’ in Seg-4, and -10, and ‘T’ in Seg-9 (weak context).
Phylogenetic comparisons of orbivirus subcore-shell ‘T2’ proteins.
In EUBV, TILV and PATAV, VP3 (encoded by Seg-3) was identified as the virion's sub-core-shell ‘T2’ protein, by comparisons with BTV proteins using BlastX. Nucleotide (nt) and amino acid (aa) identities in VP3(T2) of EUBV, TILV and PATAV, as compared to other orbiviruses, are given in Table 3 and 4. Unrooted neighbour-joining (NJ) trees were constructed using p-distance algorithm and pairwise deletion parameters for the T2 protein sequences of the different orbiviruses listed in the Table S1 (supplementary data). Two major clusters were identified (Figure 2): in which VP3(T2) of the Culicoides transmitted viruses is encoded by Seg-3 (including BTV, African horse sickness virus [AHSV], Epizootic haemorrhagic disease virus [EHDV], Wallal virus [WALV], Eubenangee virus [EUBV], Warrego virus [WARV] and Palyam virus [PALV]); while in the second group, VP3(T2) is encoded by Seg-2 of two orbivirus sub-groups that are transmitted either by ticks (Great island virus [GIV]), or by mosquitoes (Corriparta [CORV], Wongorr virus [WGRV], Peruvian horse sickness virus [PHSV], Yunnan orbivirus [YUOV]). St Croix River virus [SCRV] branches separately, representing a more distantly related orbivirus that may be a tick-virus rather than a tick-borne-virus . EUBV and TILV viruses cluster together and are distinct from the other Orbivirus species in the ‘Culicoides borne group’, although they cluster with other species that infect marsupials (Wallal virus and Warrego virus) (Figure 2).
The tree was constructed using distance matrices, generated using the p-distance determination algorithm in MEGA 5 (1000 bootstrap replicates) . Since many of the available sequences are incomplete, the analysis is based on partial sequences (aa 393 to 548, numbered with reference to the aa sequence of BTV VP3 (T2)). The numbers at nodes indicate bootstrap confidence values after 1000 replications. The tree shown in Figure 3 was drawn using same parameters. The EUBV and TILV isolates characterised in this study are shown in red font and PATAV is shown in blue font. Full names of virus isolates and accession numbers of T2 protein sequences used for comparative analysis are listed in Table S1 (supplementary data). ‘e’ and ‘w’ after serotype number indicate eastern and western strains, respectively.
In contrast VP3(T2) of PATAV branches independently from EUBV and TILV within the Culicoides borne group, clustering more closely with EHDV and BTV. Although EUBV, TILV and PATAV were initially isolated from mosquitoes, EUBV has also been isolated from Culicoides  and all three viruses group more closely with the Culicoides borne orbiviruses, suggesting that these insects may act as their biological vectors.
Phylogenetic comparisons of VP1(Pol) proteins.
The viral RNA dependent RNA polymerase (Pol) gene encoded by Seg-1 of all orbiviruses is highly conserved within the genus. Phylogenetic comparisons of this genome segment and protein have been used to classify new virus isolates at the species and genus level , , . The aa sequence of EUBV, TILV and PATAV VP1(Pol) and homologous proteins from representatives of the other Orbivirus species were compared and used to construct an unrooted NJ phylogenetic tree (Figure 3) (the accession numbers used are listed in Supplementary Table S1; percentage identities are given in Table S2 - supplementary data). As already observed for VP3(T2) (Figure 1), VP1(Pol) of EUBV, TILV and PATAV again group with other Culicoides borne orbiviruses. EUBV and TILV cluster very closely together (consistent with membership of a single virus species), while PATAV branches separately (Figure 3).
The EUBV and TILV isolates characterised in this study are shown in red font, and PATAV is shown in blue font. Full names of virus isolates and accession numbers of polymerase sequences used for comparative analysis are listed in Table S2 (supplementary data). ‘e’ and ‘w’ after serotype number indicate eastern and western strains, respectively.
Phylogenetic comparisons of outer-core VP7(T13) proteins.
The core surface protein VP7(T13) of BTV is a strongly immunodominant antigen and is the primary determinant of virus-serogroup . The aa sequence of this protein, which is highly conserved within each Orbivirus species, has provided a target for development of serogroup-specific serological diagnostic assays . The aa sequence of VP7(T13) from EUBV, TILV and PATAV, were compared to those of other orbiviruses (accession numbers are given in Table S1 - supplementary data). An unrooted phylogenetic tree, constructed using the T13 aa sequences (data not shown), shows the same topology as trees constructed for the T2 and VP1(Pol) proteins, showing separate branching of PATAV from EUBV and TILV and grouping all three with the Culicoides borne viruses.
The VP7(T13) protein of EUBV, TILV and PATAV shares 37.93% to 67.53% aa sequence identity with the Culicoides borne orbiviruses; 20.63% to 26.01% aa identity with mosquito borne orbiviruses; 21.5% to 24.5% aa identity with the tick borne orbiviruses; and only 20.41%–22.65% aa identity with the most distantly related SCRV (Table S3-supplementary data).
Relationships between EUBV, TILV and PATAV.
Sequence identity levels were calculated for RNAs and proteins of EUBV, TILV and PATAV, in comparison to members of other Orbivirus species, using the p-distance and pairwise deletion parameters in MEGA5 (Table 3 and 4). Four of the EUBV and TILV proteins share >90% aa identity: with 95.66% in the subcore-shell ‘T2’ protein; 95.14% in the core-surface and serogroup specific antigen VP7(T13); 92.1% in the polymerase VP1(Pol); and 90.84% in the capping enzyme and transmethylase VP4(CaP) (Tables 3 and 4). Based on these data, previous comparisons of other Orbivirus species confirm that EUBV and TILV belong to the same virus species (Figure 1, 2 and 3, Table 4). In contrast the sequence of outer-capsid protein VP2 is highly variable between EUBV and TILV, with only 52.2% aa identity. Based on data from BTV , ,  this indicates that they represent distinct virus ‘types’ within the same species. The second outer capsid protein, VP5 (encoded by Seg-6) is also the second most variable protein of BTV, although it can sometimes show high levels of identity between distinct serotypes . Comparisons of TILV and EUBV showed that within this limited sample group, VP5 was less variable (88.1% aa identity) than either NS3 or VP6(Hel), which have 68.6% or 70.12% aa identity respectively (Table 3).
PATAV shares <70.2% identity in VP3(T2); <65% identity in the polymerase VP1(Pol) and <57.5% aa identity in VP7(T13) with TILV or EUBV (Table 3 and 4), consistent with membership of a different Orbivirus species/serogroups , , . Among the other orbiviruses, Pata virus is most closely related to EHDV and BTV with 66.9% to 80.7% and 64.3% to 76.86% aa identity respectively in these conserved proteins (Table 3 and 4), while EUBV and TILV share between 51.6% to 69.8% aa identity with BTV and EHDV (Table 3), levels that are also consistent with membership of distinct Orbivirus species.
Most of the genome segments in EUBV and TILV are monocistronic encoding single proteins from single open reading frames (ORF). However, Seg-10 of both viruses has two in-frame initiation sites at, or near the start of the same ORF leading to translation of NS3 and NS3a (Table 1). A similar coding strategy has previously been reported for Seg-10 of BTV which encodes two related non-structural proteins (NS3 and NS3a) that are more abundantly expressed in insect rather than in mammalian cells , , . Recently, a novel non-structural protein ‘NS4’ of BTV and several other orbiviruses (which varies between 10 kDa to 22.5 kDa), was identified encoded by an alternative downstream ORF (from +2 frame) on Seg-9 (which also encodes VP6-Helicase) , , .
Seg-9 of EUBV, TILV and PATAV also has an additional down-stream ORF (in reading-frame +2) (Table 1). The 2nd ORF on Seg-9 of EUBV and TILV are in approximately the same position (at 114–368 bp (84 aa) and 117–383 bp (88 aa) respectively) and contain moderately strong Kozak sequences in each case (GGAATGA and GAGATGA). In contrast the 2nd ORF of PATAV is much further downstream on Seg-9, at 265–504 bp (80 aa), and has a weak Kozak context (AAGATGC), similar to those observed for NS4 of BTV and some other orbiviruses .
Hydrophobicity profiles of NS4 proteins from BTV, EHDV, GIV, EUBV, TILV and PATAV show broadly similar patterns of conserved domains indicating that they are generally hydrophilic (Figure S1-Supplementary data). Sequence analyses indicate that PATAV NS4 is structured as coiled-coil (cc) domains over its entire length, while EUBV NS4 contains two cc domains between aa 1 to 14 and 35 to 84 and TILV NS4 contains two cc domains between aa 2 to 17 and 33 to 88. A Pfam search indicates similarities between NS4 of PATAV, with cc domains of PROX1, a protein that interacts with EP300, which in turn interacts with nuclear components . These similarities suggest that NS4 of PATAV may also interact with the nucleus. Like NS4 of the other orbiviruses , potential monopartite and bipartite nuclear localisation signals (NLS) were identified in NS4 of EUBV, TILV and PATAV (Table S4-supplementary data). A Pfam search also identified matches between NS4 of EUBV and the integrase of bacteriophage lambda, indicating possible interaction between NS4 and nucleic acids. It has been experimentally shown that NS4 of BTV and GIV both bind DNA .
Parameters recognised by the International Committee on Taxonomy of Viruses (ICTV) for the ‘polythetic definition’ of individual Orbivirus species include: the reassortment of genome segments; genome segment migration patterns during 1% agarose gel electrophoresis (AGE); conserved terminal nucleotide sequences; serological cross-reactions; comparison of homologous genome segments or proteins by sequence analysis or cross-hybridisation; host and vector range and the nature of clinical signs induced . The majority of the existing Orbivirus species were initially recognised as distinct ‘serogroups’. However, reference antisera for these existing species are not widely available, making serological identification of new virus isolates more difficult. Data concerning the potential for reassortment of new orbivirus isolates with members of existing species would also require access to reference strains and would be very labour intensive. In contrast, nt and deduced aa sequence data generated for each species can be easily and reliably disseminated and can be used to analyse and identify new or existing virus isolates , , , , .
Viruses within a single Orbivirus species/serogroup usually have similar dsRNA migration profiles during in 1% agarose gel electrophoresis (AGE) . EUBV, TILV and PATAV show a 3-3-3-1 RNA migration during AGE, broadly similar to those of BTV and EHDV, suggesting relatively close relationships with the members of these virus species. The RNA-AGE migration patterns of EUBV and TILV are almost identical, suggesting that they belong to the same species. However, PATAV shows a number of differences, particularly in the migration of Seg-7 to 10, compared to EUBV or TILV, suggesting that it belongs to a different species.
The rationale for the current inclusion of Pata virus (PATAV) in the species Eubenangee virus does not appear to be recorded. It does not cross-react strongly in serological assays with other EUBV isolates and it is not closely related to EUBV by hybridrization , , , leading to suggestions that the current classification of PATAV should be re-examined , , . PATAV does show low level cross-reactivity in complement fixation (CF) tests with BTV and EHDV serogroups ,  and it has been suggested that it could be reclassified as an EHDV , . However, no cross hybridization or reassortment was detected between PATAV and BTV or EHDV .
Low level cross-reactions have previously been shown between EUBV, and BTVs or EHDVs in cross-hybridization and serological assays (including CF and agar gel immunoprecipitation tests) , , , reflecting a common ancestry , , , , . PATAV is not closely related to other Eubenangee viruses by hybridization , and hybridization or gene reassortment data indicate that it is not a BTV or EHDV .
Recent advancements in molecular biology and sequencing technologies  have allowed phylogenetic comparisons to be used as major tools for orbivirus identification, development of diagnostic tests and taxonomic classification. Sequence data generated for conserved orbivirus genes (e.g. the T2, Polymerase or T13 protein genes) have previously been used for phylogenetic comparisons and taxonomic classification , . However, a lack of sequence data for reference strains of all 22 Orbivirus species remains a barrier for molecular identification, diagnostic assay development and taxonomic classification of novel isolates.
This study was therefore designed to generate full-genome sequences for available members of the species Eubenangee virus (EUBV, TILV and PATAV) as part of a wider programme generating representative sequences for all of the different Orbivirus species , , , , , , , , , .
Although EUBV and TILV have been isolated from both Culex annulirostris and Culicoides marksi, EUBV multiplied to high titres in the recognised orbivirus vector Culicoides variipennis after both intra-thoracic inoculation and oral ingestion, but only replicated in C. nubeculosus (usually regarded as a non-vector species) after intra-thoracic inoculation . Earlier studies have reported a highly conserved Arg-Gly-Asp (RGD) motif at position 168–170 in the VP7(T13) core-surface protein of the Culicoides borne orbiviruses BTV, EHDV and AHSV, suggesting that it could have a role in core particle attachment to Culicoides cells , , . An RGD motif was not observed in EUBV and TILV, but was present at position 168–170 in VP7(T13) of PATAV, reflecting its closer overall similarity to BTV and EHDV, and potentially implicating Culicoides spp. as biological vectors.
The G+C content of the mosquito borne orbiviruses is between 36.72% in Peruvian horse sickness virus (PHSV) and 41.55% in Yunnan orbivirus (YUOV), in the tick borne orbiviruses it is between 57.29% in Great Island virus (GIV) and 51.93% in St Croix River virus (SCRV), while the Culicoides borne orbiviruses have intermediate G+C content from 39.89% in Chuzan virus (CHUV) to 45.89% in equine encephalosis virus (EEV) . The G+C content of EUBV, TILV and PATAV is 44.99%, 45.143% and 42.2% respectively, within the range of the Culicoides borne orbiviruses, again suggesting Culicoides as a biological vector.
The orbivirus sub-core-shell ‘T2’, polymerase ‘Pol’ and outer-core ‘T13’ proteins are highly conserved with >83%, >73% and >73% aa identity respectively within a single Orbivirus species , , . The highest inter-species identity levels for T2 and Pol that have so far been detected (80% and 73% in T2 and Pol respectively) are between isolates of BTV and EHDV, reflecting their close relationship, as well as the large number of different isolates that have been sequenced from these two virus species , , . EUBV and TILV share >92% aa identity in these highly conserved proteins, confirming that they belong to the same virus species. In contrast they show lower levels of aa identity with members of other Orbivirus species, with highest similarities to EHDV and BTV. PATAV shows lower levels of identity with the Eubenangee viruses (EUBV and TILV) supporting earlier hybridization and reassortment studies ,  indicating that PATAV is a not a member of this virus species. Amongst the other orbiviruses, PATAV also shares highest aa identity levels with EHDV and BTV proteins (Table 3) indicating that it belongs to a closely related but distinct species.
The orbivirus NS4 protein is highly variable in size, ranging from 77 aa in BTV to 190 aa in GIV . NS4 of EUBV, TILV and PATAV is relatively small size at 84 aa, 88 aa and 80 aa respectively. Further in vivo studies will confirm the functional role of these proteins in the infected cell.
Previous phylogenetic studies of mitochondrial genes have indicated that ticks represent ancestors for other arthropods . Phylogenetic analysis of the conserved genes and proteins (Figure 2 and 3), shows phylogenetic segregation between the orbiviruses that are transmitted by Culicoides (which have VP3(T2)) and those transmitted by ticks or mosquitoes, (in which the homologous protein is VP2(T2)). This difference appears to be primarily due to the presence of a significantly larger outer-capsid ‘VP2’ protein in the Culicoides borne orbiviruses. Analyses of the orbivirus T2 (Figure 2), polymerase proteins (Figure 3) and T13 proteins (data not shown), show similar phylogenetic separation of the Culicoides, mosquito and tick borne orbiviruses, providing evidence of co-evolution or ‘co-speciation’ with their vectors .
Data presented here confirm that EUBV and TILV are both members of the Eubenangee virus species/serogroup. However, they contain <52% aa identity in outer capsid protein VP2. Based on data from BTV and EHDV , , this indicates that they belong to different serotypes - EUBV-1 and EUBV-2 respectively. These data also support the reclassification of Pata virus as the prototype (PATAV-1) of a distinct and novel Orbivirus species. A proposal to recognise the species ‘Pata virus’ has therefore been sent to the Reoviridae study Group of ICTV. The availability of full-genome sequences for these reference strains, will help to identify novel Eubenangee and Pata viruses, providing a basis for molecular epidemiology studies to determine strain movements and help identify relevant arthropod vectors. They will also help in the development of improved diagnostic assays for the TSDS (e.g. by RT-PCR).
Materials and Methods
Isolates of Eubenangee viruses which had been stored at −80°C, were obtained from the Orbivirus Reference Collection (ORC) at the Institute for Animal Health (IAH), including: EUBV (ORC Strain Number: AUS1963/01); TILV (AUS1978/03); and PATAV (CAF1968/01). These samples were taken from naturally infected animals in the field, by qualified veterinarians, as part of normal diagnostic testing procedures in the respective countries and did not therefore require Ethics Committee approval. TILV was propagated in BHK-21 cells (clone 13 obtained from European Collection of Animal cell Cultures (ECACC – 84100501), while EUBV and PATAV were grown in BSR cells (a clone of BHK) , at 37°C in Dulbecco's minimum essential medium (DMEM) supplemented with antibiotics (100 units/ml penicillin and 100 µg/ml streptomycin) and 2 mM glutamine. Infected cell cultures were incubated at 37°C until they show widespread (100%) cytopathic effects (CPE). Then viruses were harvested, aliquoted and used for the viral dsRNA extraction, or stored in the orbivirus reference collection (ORC) at −80°C.
Preparation of viral dsRNA
Intact genomic dsRNA was extracted from EUBV, TILV or PATAV infected cell cultures, using a guanidinium isothiocyanate extraction procedure, as described by Attoui et al . Briefly, the infected cell pellet was lysed in 1 ml of commercially available TRIZOL® reagent (Invitrogen), 0.2 volume of choloroform was added, mixed by vortexing and the mixture incubated on ice for 10 min. The supernatant, containing total RNA, was separated from the cellular debris and DNA by centrifuging at 10,000× g for 10 min at 4°C. Single stranded RNA (ssRNA) was removed by 2 M LiCl precipitation at 4°C overnight, followed by centrifugation at 10,000× g for 5 min. An equal volume of isopropanol, containing 750 mM ammonium acetate, was added to the supernatant then mixed and the viral dsRNA allowed to precipitate for a minimum of 2 hours at −20°C. The dsRNA was pelleted by centrifugation at 10,000× g for 10 min. The pellet was washed with 70% ethanol, air dried and suspended in nuclease free water (NFW). The RNA was either used immediately or stored at −20°C.
Reverse transcription of dsRNA, and PCR amplification
Viral genome segments of EUBV, TILV and PATAV were reverse-transcribed into cDNA using the full-length amplification of cDNAs (FLAC) technique described by Maan et al . Briefly, a 35 base oligonucleotide ‘anchor-primer’, with a phosphorylated 5′ terminus, was ligated to the 3′ ends of the viral dsRNAs using the T4 RNA ligase, followed by reverse transcription using RT system (Promega). The resulting cDNAs were amplified using complementary primers to the anchor primer. The resulting cDNA amplicons were analyzed by agarose gel electrophoresis. For cloning purposes, a high fidelity KOD polymerase enzyme (Novagen) was used in the PCR.
Cloning and sequencing of cDNA segments
Amplified cDNAs were purified and cloned. TILV genes were cloned into the Strataclone blunt-end PCR cloning vector ‘pSC-B-amp/kan’ supplied in the StrataClone Blunt PCR cloning kit (Stratagene). EUBV and PATAV amplicons were cloned into the ‘pCR®-Blunt’ vector supplied with the Zero Blunt® PCR Cloning Kit (Invitrogen). Recombinant plasmid-vectors containing TILV inserts were transformed into Solopack® competent cells (Agilent Technologies), while EUBV and PATAV plasmids were transformed into One Shot® TOP10 competent cells, supplied with the respective cloning kits. Clones containing relevant inserts were identified by touch PCR using M13 universal primers. Plasmids were extracted from the clones identified, using the QIAprep Spin MiniPrep Kit (Qiagen). The plasmids and PCR products were sequenced using an automated ABI 3730 DNA sequencer (Applied Biosystems).
Sequence analysis and phylogenetic tree construction
‘Raw’ ABI sequence data, was assembled into ‘contigs’ using the SeqManII sequence analysis package (DNAstar version 5). The ORFs of EUBV and TILV genome segments were identified using EditSeq and NCBI ORF finder, and translated to aa sequences for further analysis. Putative functions were assigned to individual proteins by comparisons to sequences in GenBank and identification of homologous BTV proteins, using BlastX (http://blast.ncbi.nlm.nih.gov/Blast.cgi?CMD=Web&PAGE_TYPE=BlastHome). Multiple alignments of consensus sequences were performed using Clustal X (Version 2.0) , Clustal Omega (http://www.ebi.ac.uk/Tools/msa/clustalo/) and MAFFT (http://mafft.cbrc.jp/alignment/server/) to ensure proper alignment. Pairwise distance (aa and nt) calculations and phylogenetic trees constructions were done using MEGA 5 software  with the p-distance parameter and neighbor-joining method . The hydrophobicity profile of different NS4 proteins was analysed using the Kyte and Doolittle hydrophobicity plot with a window size of 11 amino acids (aa) . Sequence relatedness to proteins and domains were assessed by comparing with the pfam database (Available at http://pfam.sanger.ac.uk/search). The presence of ‘coiled-coils’ was analysed using the program ‘COILS’ (available at http://www.ch.embnet.org/software/COILS_form.html). Nuclear localisation signals were predicted using cNLS Mapper (available at http://nls-mapper.iab.keio.ac.jp/cgi-bin/NLS_Mapper_form.cgi).
Hydrophobicity profiles of orbivirus NS4 proteins. Superimposed hydrophobicity profiles based on multiple alignment of orbivirus NS4 amino acid sequences, generated using Clustal X2. The residue numbers are relative to NS4 of GIV. GIV NS4 (red line), BTV NS4 (blue line), EUBV NS4 (green line), TILV NS4 (Magenta line), PATAV NS4 (purple line) and EHDV (black line).
Nucleotide accession numbers for sequences used in phylogenetic analysis.
Percent aa identity of EUBV, TILV and PATAV Polymerase (Pol) protein with other orbiviruses.
Identity levels in the outer-core protein VP7(T13) of EUBV, TILV and PATAV compared to other Orbiviruses.
Nuclear localization signals (NLS) in NS4 of Eubenangee, Tilligerry and Pata viruses.
The authors thank international colleagues who provided virus isolates for analyses and comparisons.
Conceived and designed the experiments: MB SM NSM HA PPCM. Performed the experiments: MB SM NSM KN. Analyzed the data: MB SM NSM HA PPCM. Contributed reagents/materials/analysis tools: MB SM NSM PPCM HA KN IP RL PK JB. Wrote the paper: MB SM NSM PPCM.
- 1. Belaganahalli MN, Maan S, Maan NS, Tesh R, Attoui H, et al. (2011) Umatilla virus genome sequencing and phylogenetic analysis: identification of stretch lagoon orbivirus as a new member of the Umatilla virus species. PLoS One 6: e23605.
- 2. Brown SE, Gorman BM, Tesh RB, Knudson DL (1992) Isolation of bluetongue and epizootic hemorrhagic disease viruses from mosquitoes collected in Indonesia. Vet Microbiol 32: 241–252.
- 3. Mertens PPC, Maan S, Samuel A, Attoui H (2005) Orbiviruses, Reoviridae. In: Fauquet CM, Mayo MA, Maniloff J, Desselberger U, Ball LA, editors. Virus Taxonomy Eighth Report of the International Committee on Taxonomy of Viruses. London: Elsevier/Academic Press. pp. 466–483.
- 4. Martins LC, Diniz JA, Silva EV, Barros VL, Monteiro HA, et al. (2007) Characterization of Minacu virus (Reoviridae: Orbivirus) and pathological changes in experimentally infected newborn mice. Int J Exp Pathol 88: 63–73.
- 5. Vieira Cde M, Nunes MR, da Silva EV, Carvalho VL, Nunes Neto JP, et al. (2009) Full-length sequencing and genetic characterization of Breu Branco virus (Reoviridae, Orbivirus) and two related strains isolated from Anopheles mosquitoes. J Gen Virol 90: 2183–2190.
- 6. Victoria JG, Kapoor A, Dupuis K, Schnurr DP, Delwart EL (2008) Rapid identification of known and new RNA viruses from animal tissues. PLoS Pathog 4: e1000163.
- 7. Karabatsos N (1985) International catalogue of arboviruses including certain other viruses of vertebrates. San Antonio: American Society of Tropical Medicine and Hygiene.
- 8. Attoui H, Maan SS, Anthony SJ, Mertens PPC (2009) Bluetongue virus, other orbiviruses and other reoviruses: Their relationships and taxonomy. In: Mellor PS, Baylis M, Mertens PPC, editors. Bluetongue monograph. 1 ed. London: Elsevier/Academic Press. pp. 23–552.
- 9. Rose KA, Kirkland PD, Davies RJ, Cooper DW, Blumstein DT (2000) An epizootic of sudden death in Tammar Wallabies (Macropus eugenii). Proceedings AAZV and IAAAM joint conference 166–170.
- 10. Doherty RL, Whitehead RH, Wetters EJ, Gorman BM, Carley JG (1970) A survey of antibody to 10 arboviruses (Koongol Group, Mapputta group and ungrouped) isolated in Queensland. Trans R Soc Trop Med Hyg 64: 748–753.
- 11. Gard G, Marshall ID, Woodroofe GM (1973) Annually recurrent epidemic polyarthritis and Ross River virus activity in a coastal area of New South Wales. II. Mosquitoes, viruses, and wildlife. Am J Trop Med Hyg 22: 551–560.
- 12. Gorman BM, Taylor J (1978) The RNA genome of Tilligerry virus. Aust J Exp Biol Med Sci 56: 369–371.
- 13. Schnagl RD, Holmes IH (1975) Electron microscopy of Japanaut and Tilligerry viruses: two proposed members of the orbivirus group. Aust J Biol Sci 28: 425–432.
- 14. Pritchard LI, Kirkland PD, Melville LF, Weir R, Lunt R, et al. (2001) Molecular analyses of orbiviruses from emerging wildlife diseases. In: Brown MD, Aaskov JG, Ryan PA, editors. pp. 282–287. Arbovirus research in Australia: papers from 8th Arbovirus Research Symposium, 4th Mosquito Control Association of Australia Symposium, 3–7July 2000 South Stradbroke Island, Australia: Queensland University of Technology, QIMR.
- 15. Kirkland P (2005) Epidemic viral diseases of wildlife - sudden death in tammar wallabies, blind kangaroos, herpesviruses in pilchards-what next? Microbiology Australia 82–84.
- 16. TSDS (2011) Tammar Wallaby Sudden Death Syndrome (TSDS) Fact sheet, Australian Wildlife Health Network http://www.wildlifehealth.org.au/AWHN_Admin/ManageWebsite%5CFactSheets%5CUploadedFiles/119/Tammar%20Wallaby%20Sudden%20Death%20Syndrome%20(TSDS)%204%20Feb%202010%20(1.1).pdf (Accessed on 2011-09-06).
- 17. ARWH (2011) Tammar Wallaby Mortality Alert 21 JANUARY 2011. http://www.arwh.org/sites/default/files/files-uploads/2011%20ARWH%20Tammar%20Wallaby%20Mortality%20Alert%20JANUARY%202011.pdf (accessed on 2011-09-06). In: Australia TCS, editor: Australia Registry of Wildlife Health.
- 18. AHSurveillance (2011) Tammar wallaby sudden death syndrome investigations. http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0003/388452/AHNewsJan-Mar2011.pdf (Accessed on 2011-09-06). Report Number: 2011/1 Report Number: 2011/1.
- 19. Borden EC, Shope RE, Murphy FA (1971) Physicochemical and morphological relationships of some arthropod-borne viruses to bluetongue virus–a new taxonomic group. Physiocochemical and serological studies. J Gen Virol 13: 261–271.
- 20. Maan NS, Maan S, Nomikou K, Belaganahalli MN, Bachanek-Bankowska K, et al. (2011) Serotype specific primers and gel-based rt-PCR assays for ‘typing’ african horse sickness virus: identification of strains from Africa. PLoS One 6: e25686.
- 21. Maan NS, Maan S, Nomikou K, Johnson DJ, El Harrak M, et al. (2010) RT-PCR assays for seven serotypes of epizootic haemorrhagic disease virus & their use to type strains from the Mediterranean region and North America. PLoS One 5:
- 22. Mertens PP, Maan NS, Prasad G, Samuel AR, Shaw AE, et al. (2007) Design of primers and use of RT-PCR assays for typing European bluetongue virus isolates: differentiation of field and vaccine strains. J Gen Virol 88: 2811–2823.
- 23. Anthony S, Jones H, Darpel KE, Elliott H, Maan S, et al. (2007) A duplex RT-PCR assay for detection of genome segment 7 (VP7 gene) from 24 BTV serotypes. J Virol Methods 141: 188–197.
- 24. Maan S, Maan NS, Ross-smith N, Batten CA, Shaw AE, et al. (2008) Sequence analysis of bluetongue virus serotype 8 from the Netherlands 2006 and comparison to other European strains. Virology 377: 308–318.
- 25. Maan S, Maan NS, Nomikou K, Batten C, Antony F, et al. (2011) Novel bluetongue virus serotype from Kuwait. Emerg Infect Dis 17: 886–889.
- 26. Maan S, Rao S, Maan NS, Anthony SJ, Attoui H, et al. (2007) Rapid cDNA synthesis and sequencing techniques for the genetic study of bluetongue and other dsRNA viruses. J Virol Methods 143: 132–139.
- 27. Mertens PP, Sangar DV (1985) Analysis of the terminal sequences of the genome segments of four orbiviruses. Virology 140: 55–67.
- 28. Attoui H, Stirling JM, Munderloh UG, Billoir F, Brookes SM, et al. (2001) Complete sequence characterization of the genome of the St Croix River virus, a new orbivirus isolated from cells of Ixodes scapularis. J Gen Virol 82: 795–804.
- 29. Attoui H, Mohd Jaafar F, Belhouchet M, Aldrovandi N, Tao S, et al. (2005) Yunnan orbivirus, a new orbivirus species isolated from Culex tritaeniorhynchus mosquitoes in China. J Gen Virol 86: 3409–3417.
- 30. Gumm ID, Newman JF (1982) The preparation of purified bluetongue virus group antigen for use as a diagnostic reagent. Arch Virol 72: 83–93.
- 31. Maan S, Maan NS, van Rijn PA, van Gennip RG, Sanders A, et al. (2010) Full genome characterisation of bluetongue virus serotype 6 from the Netherlands 2008 and comparison to other field and vaccine strains. PLoS One 5: e10323.
- 32. Maan S, Maan NS, Samuel AR, Rao S, Attoui H, et al. (2007) Analysis and phylogenetic comparisons of full-length VP2 genes of the 24 bluetongue virus serotypes. J Gen Virol 88: 621–630.
- 33. Belhouchet M, Mohd Jaafar F, Tesh R, Grimes J, Maan S, et al. (2010) Complete sequence of Great Island virus and comparison with the T2 and outer-capsid proteins of Kemerovo, Lipovnik and Tribec viruses (genus Orbivirus, family Reoviridae). J Gen Virol 91: 2985–2993.
- 34. French TJ, Inumaru S, Roy P (1989) Expression of two related nonstructural proteins of bluetongue virus (BTV) type 10 in insect cells by a recombinant baculovirus: production of polyclonal ascitic fluid and characterization of the gene product in BTV-infected BHK cells. J Virol 63: 3270–3278.
- 35. Guirakhoo F, Catalan JA, Monath TP (1995) Adaptation of bluetongue virus in mosquito cells results in overexpression of NS3 proteins and release of virus particles. Arch Virol 140: 967–974.
- 36. Beaton AR, Rodriguez J, Reddy YK, Roy P (2002) The membrane trafficking protein calpactin forms a complex with bluetongue virus protein NS3 and mediates virus release. Proc Natl Acad Sci U S A 99: 13154–13159.
- 37. Firth AE (2008) Bioinformatic analysis suggests that the Orbivirus VP6 cistron encodes an overlapping gene. Virol J 5: 48.
- 38. Belhouchet M, Mohd Jaafar F, Firth AE, Grimes JM, Mertens PP, et al. (2011) Detection of a fourth orbivirus non-structural protein. PLoS One 6: e25697.
- 39. Hasan S, Hassa PO, Imhof R, Hottiger MO (2001) Transcription coactivator p300 binds PCNA and may have a role in DNA repair synthesis. Nature 410: 387–391.
- 40. Attoui H, Mendez-Lopez MR, Rao S, Hurtado-Alendes A, Lizaraso-Caparo F, et al. (2009) Peruvian horse sickness virus and Yunnan orbivirus, isolated from vertebrates and mosquitoes in Peru and Australia. Virology 394: 298–310.
- 41. Marshall ID, Woodroofe GM, Gard GP (1980) Arboviruses of coastal south-eastern Australia. Aust J Exp Biol Med Sci 58: 91–102.
- 42. Gonzalez HA, Knudson DL (1988) Intra- and inter-serogroup genetic relatedness of orbiviruses. I. Blot hybridization of viruses of Australian serogroups. J Gen Virol 69(Pt 1): 125–134.
- 43. Brown SE, Gonzalez HA, Bodkin DK, Tesh RB, Knudson DL (1988) Intra- and inter-serogroup genetic relatedness of orbiviruses. II. Blot hybridization and reassortment in vitro of epizootic haemorrhagic disease serogroup, bluetongue type 10 and Pata viruses. J Gen Virol 69(Pt 1): 135–147.
- 44. Gorman BM, Taylor J, Walker PJ (1983) Orbiviruses. In: Joklik WK, editor. The Reoviridae. New York and London: Plenum Press. pp. 287–357.
- 45. Moore DL, Lee VH (1972) Antigenic relationship between the virus of epizootic haemorrhagic disease of deer and bluetongue virus. Brief report. Arch Gesamte Virusforsch 37: 282–284.
- 46. Gorman BM (1979) Variation in orbiviruses. J Gen Virol 44: 1–15.
- 47. Della-Porta AJ (1985) Classification of orbiviruses: a need for supergroups of genera. Prog Clin Biol Res 178: 267–274.
- 48. Anthony SJ, Maan N, Maan S, Sutton G, Attoui H, et al. (2009) Genetic and phylogenetic analysis of the core proteins VP1, VP3, VP4, VP6 and VP7 of epizootic haemorrhagic disease virus (EHDV). Virus Res 145: 187–199.
- 49. Maan S, Maan NS, Nomikou K, Veronesi E, Bachanek-Bankowska K, et al. (2011) Complete genome characterisation of a novel 26th bluetongue virus serotype from kuwait. PLoS One 6: e26147.
- 50. Anthony SJ, Maan S, Maan N, Kgosana L, Bachanek-Bankowska K, et al. (2009) Genetic and phylogenetic analysis of the outer-coat proteins VP2 and VP5 of epizootic haemorrhagic disease virus (EHDV): comparison of genetic and serological data to characterise the EHDV serogroup. Virus Res 145: 200–210.
- 51. Mellor PS, Jennings M (1980) Replication of eubenangee virus in Culicoides nuberculosus (Mg.) and Culicoides variipennis (Coq.). Arch Virol 63: 203–208.
- 52. Tan BH, Nason E, Staeuber N, Jiang W, Monastryrskaya K, et al. (2001) RGD tripeptide of bluetongue virus VP7 protein is responsible for core attachment to Culicoides cells. J Virol 75: 3937–3947.
- 53. Basak AK, Gouet P, Grimes J, Roy P, Stuart D (1996) Crystal structure of the top domain of African horse sickness virus VP7: comparisons with bluetongue virus VP7. J Virol 70: 3797–3806.
- 54. Wilson K, Cahill V, Ballment E, Benzie J (2000) The complete sequence of the mitochondrial genome of the crustacean Penaeus monodon: are malacostracan crustaceans more closely related to insects than to branchiopods? Mol Biol Evol 17: 863–874.
- 55. Sato M, Maeda N, Yoshida H, Urade M, Saito S (1977) Plaque formation of herpes virus hominis type 2 and rubella virus in variants isolated from the colonies of BHK21/WI-2 cells formed in soft agar. Arch Virol 53: 269–273.
- 56. Attoui H, Billoir F, Cantaloube JF, Biagini P, de Micco P, et al. (2000) Strategies for the sequence determination of viral dsRNA genomes. J Virol Methods 89: 147–158.
- 57. Larkin MA, Blackshields G, Brown NP, Chenna R, McGettigan PA, et al. (2007) Clustal W and Clustal X version 2.0. Bioinformatics 23: 2947–2948.
- 58. Tamura K, Peterson D, Peterson N, Stecher G, Nei M, et al. (2011) MEGA5: Molecular Evolutionary Genetics Analysis using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Mol Biol Evol.
- 59. Saitou N, Nei M (1987) The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 4: 406–425.
- 60. Kyte J, Doolittle RF (1982) A simple method for displaying the hydropathic character of a protein. J Mol Biol 157: 105–132.