Beet soil-borne mosaic virus RNA-3 is replicated and encapsidated in the presence of BNYVV RNA-1 and -2 and allows long distance movement in Beta macrocarpa

Beet soil-borne mosaic virus (BSBMV) and Beet necrotic yellow vein virus (BNYVV) belong to the Benyvirus genus. BSBMV has been reported only in the United States, while BNYVV has a worldwide distribution. Both viruses are vectored by Polymyxa betae and possess similar host ranges, particle number and morphology. BNYVV and BSBMV are not serologically related but they have similar genomic organizations. Field isolates usually consist of four RNA species but some BNYVV isolates contain a fifth RNA. RNAs 1 and 2 are essential for infection and replication while RNAs 3 and 4 play important roles in plant and vector interactions, respectively. Nucleotide and amino acid analyses revealed that BSBMV and BNYVV are sufficiently different to be classified as two species. Complementary base changes found within the BSBMV RNA-3 5′ UTR made it resemble to BNYVV 5′ RNA-3 structure whereas the 3′ UTRs of both species were more conserved. cDNA clones were obtained, and allowed complete copies of BSBMV RNA-3 to be trans-replicated, trans-encapsidated by the BNYVV viral machinery. Long-distance movement was observed indicating that BSBMV RNA-3 could substitute BNYVV RNA-3 for systemic spread, even though the p29 encoded by BSBMV RNA-3 is much closer to the RNA-5-encoded p26 than to BNYVV RNA-3-encoded p25. Competition occurred when BSBMV RNA-3-derived replicons were used together with BNYVV-derived RNA-3 but not when the RNA-5-derived component was used. Exploitation of the similarities and divergences between BSBMV and BNYVV should lead to a better understanding of molecular interactions between Benyviruses and their hosts.     

Complete nucleotide sequence and genome organization of Beet soilborne mosaic virus, a proposed member of the genus Benyvirus

Summary.  The complete nucleotide sequences of RNAs 1 to 4 of Beet soilborne mosaic virus (BSBMV) were determined. The genomic organization of BSBMV is identical to Beet necrotic yellow vein virus (BNYVV), the type species of the genus Benyvirus. BSBMV RNA1 encodes a single large open reading frame (ORF) with similar replicase-associated motifs identified for BNYVV. BSBMV RNA2 has six potential ORFs with an organization resembling BNYVV RNA2. RNA3 and RNA4 resemble the analogous BNYVV RNAs, which encode proteins associated with symptom development and fungal transmission, respectively. The predicted ORFs on BNYVV and BSBMV reveal 23% to 83% amino acid identity and the overall nucleotide sequences are 35% to 77% identical. Based on sequence analyses, BSBMV is a new benyvirus that can be distinguished from BNYVV. Received February 20, 2001 Accepted August 2, 2001     

Beet soil-borne mosaic virus RNA-4 encodes a 32 kDa protein involved in symptom expression and in virus transmission through Polymyxa betae

Beet soil-borne mosaic virus (BSBMV), like Beet necrotic yellow vein virus (BNYVV), is a member of the Benyvirus genus and both are transmitted by Polymyxa betae. Both viruses possess a similar genomic organization: RNA-1 and -2 are essential for infection and replication while RNA-3 and -4 play important roles in disease development and vector-mediated infection in sugar beet roots. We characterized a new species of BSBMV RNA-4 that encodes a 32 kDa protein and a chimeric form of BSBMV RNA-3 and -4. We demonstrated that BSBMV RNA-4 can be amplified by BNYVV RNA-1 and -2 in planta, is involved in symptoms expression on Chenopodium quinoa plants and can also complement BNYVV RNA-4 for virus transmission through its vector P. betae in Beta vulgaris plants. Using replicon-mediated expression, we demonstrate for the first time that a correct expression of RNAs-4 encoded proteins is essential for benyvirus transmission.     

Molecular characterization of two Chinese isolates of <Emphasis Type="Italic">Beet mosaic virus</Emphasis>

The complete genomic sequences of Beet mosaic virus Xinjiang (BtMV-XJ) and Inner Mongolia (BtMV-IM) isolates from China were determined and compared with US and German isolates, reported previously. Results showed that viral genome of the two isolates both comprise 9,591 nucleotides, and contain the large single open reading frame (ORF) encoding a single polyprotein of 3,085 amino acid residues, from which ten putative functional proteins may be produced by autolytic cleavage processing as the US (BtMV-Wa) and German (BtMV-G) isolates. Sequence comparisons showed that BtMV-XJ shared 89.8% and 98.3% overall nucleotide identity with BtMV-Wa and BtMV-G isolates, and BtMV-IM exhibited the overall identities of 91.6% and 93.8% with BtMV-Wa and BtMV-G, respectively. Further, analyses revealed that BtMV-XJ shared higher identities in almost every region to BtMV-G than to BtMV-Wa both at the nucleotide and the amino acid levels. While BtMV-IM in the regions (6,666–7,671 and 7,672–9,591) showed highest homology with BtMV-XJ and BtMV-G, especially, after nt 7,672 with similarity up to 99.2% with BtMV-G; the region (2,331–4,083) showed highest identity (98.0% nt identity) with BtMV-Wa. That suggested BtMV-XJ had a more close relationship to BtMV-G, while BtMV-IM was more likely to be a natural recombination virus. In addition, phylogenetic analysis of the available BtMV CP sequences showed that BtMV isolates fell into two distinct groups: Euroasia group (Europe and China) and America group (USA). To the best of our knowledge, this study reported the complete sequences of two BtMV isolates from Asia for the first time. H. Xiang and Y.-H. Han contributed equally to this paper.     

Genome characterization and genetic diversity of beet curly top Iran virus: a geminivirus with a novel nonanucleotide

Beet curly top Iran virus (BCTIV) was previously reported as a distinct curtovirus in Iran. Complete nucleotide sequences of three BCTIV isolates, one each from central, southern, and south eastern Iran were determined to be 2844, 2844, and 2845 nt long, respectively. BCTIV shared highest nucleotide sequence identity (52.3%) with Spinach curly top virus (SpCTV) and lowest identity (46.6%) with Horseradish curly top virus (HrCTV). The BCTIV genome comprises three virion-sense (V1, V2, and V3) and two complementary-sense (C1 and C2) ORFs. ORFs C3 and C4 were not found in BCTIV genome. Based on a comparison of nucleotide sequence identity of individual genes, the three virion-sense ORFs were 72.7–79.9% related to the corresponding ORFs of curtoviruses, whereas no significant relationship was found between the C1 and C2 ORFs of BCTIV and curtoviruses. These two ORFs, however, were only distantly related with those of mastreviruses. Similar to the latter viruses, the BCTIV genome comprises two intergenic regions. The BCTIV large intergenic region included a sequence capable of forming a stem loop structure and a novel nonanucleotide (TAAGATT/CC) with a unique nick site. Phylogenetic analysis using deduced amino acid sequence of individual ORFs revealed that the V2 and V3 ORFs are monophyletic and the V1 ORF is classified with the related ORF of curtoviruses. Whereas the two complementary-sense ORFs are grouped with those of mastreviruses. Computer-based prediction suggested that BCTIV has a chimeric genome which may have arisen by a recombination event involving curto- and mastrevirus ancestors. Percent nucleotide sequence identities of the coat protein gene of ten isolates of BCTIV, collected from a wide range of geographical regions in Iran, varied from 87.1 to 99.9, with the isolates being distributed between two subgroups. Based on biological and molecular properties, BCTIV is proposed as a new member of the genus Curtovirus.     

Complete genomic RNA sequence of the Polish <Emphasis Type="Italic">Pepino mosaic virus</Emphasis> isolate belonging to the US2 strain

We have determined the complete nucleotide and amino acid sequences of the Polish Pepino mosaic virus (PepMV) isolate marked as PepMV-PK. The PepMV-PK genome consists of a single positive-sense RNA strand of 6412-nucleotide-long that contains five open reading frames (ORFs). ORF1 encodes the putative viral polymerase (RdRp), ORFs 2–4 the triple gene block (TGB 1–3), and ORF5-coat protein CP. Two short untranslated regions flank the coding ones and there is a poly (A) tail at the 3′ end of the genomic RNA. Thus, the genome organization of PepMV-PK is that of a typical member of the genus Potexvirus. Phylogenetic analysis based on full-length genomes of PepMV sequences showed that PepMV-PK was most closely related to the Ch2 isolate from Chile. Comparison of PepMV-PK and Ch2 showed the following nucleotide identities: 98% for the RdRp, 99% for the CP genes, and 98, 99, and 98% for the TGB1, TGB2, and TBG3, respectively. This high level of nucleotide sequence identity between the Chilean and Polish PepMV-PK isolates suggest their common origin.     

Low genetic diversity of Squash vein yellowing virus in wild and cultivated cucurbits in the U.S. suggests a recent introduction

Squash vein yellowing virus (SqVYV) isolates were collected from cultivated and weedy cucurbits representing major hosts and locations in the U.S. and analyzed to better understand the diversity and population structure. No differences in symptoms were observed in field-collected isolate source plants or subsequently inoculated greenhouse plants, and the complete genome of an SqVYV isolate from a wild cucurbit host (smellmelon, Cucumis melo var. dudaim) was highly similar (99.4% nucleotide identity, 99.3% amino acid identity) to the previously published type isolate from squash. Although analysis of the coat protein (CP) and two serine proteases (P1a and P1b) sequences for 41 isolates showed little diversity across seven years of sampling, it revealed two distinct groups of SqVYV isolates with low intra-group diversity. Our analyses also suggested that recombination had occurred between SqVYV isolates, similar to other ipomoviruses. Selection pressures on the genome regions analyzed were negative indicating purifying selection was occurring. The magnitude of negative selection in SqVYV was consistent with what has been reported for other ipomoviruses, and was greatest for the CP and least for the P1b. The observed genetic diversity was similar to that reported for Cucumber vein yellowing virus but less than that reported for Sweet potato mild mottle virus, Cassava brown streak virus and Ugandan cassava brown streak virus. Collectively, these results indicate that the current U.S. population of SqVYV has undergone a recent genetic bottleneck and was introduced from elsewhere.     

Two Crinivirus-specific proteins of Lettuce infectious yellows virus (LIYV), P26 and P9, are self-interacting

Interactions of Lettuce infectious yellows virus (LIYV)-encoded proteins were tested by yeast-two-hybrid (Y2H) assays. LIYV-encoded P34, Hsp70h, P59, CP, CPm, and P26 were tested in all possible pairwise combinations. Interaction was detected only for the P26–P26 combination. P26 self-interaction domains were mapped using a series of N- and C-terminal truncations. Orthologous P26 proteins from the criniviruses Beet pseudoyellows virus (BPYV), Cucurbit yellow stunting disorder virus (CYSDV), and Lettuce chlorosis virus (LCV) were also tested, and each exhibited strong self-interaction but no interaction with orthologous proteins. Two small putative proteins encoded by LIYV RNA2, P5 and P9, were also tested for interactions with the six aforementioned LIYV proteins and each other. No interactions were detected for P5, but P9–P9 self-interaction was detected. P26- and P9-encoding genes are present in all described members of the genus Crinivirus, but are not present in other members of the family Closteroviridae. LIYV P26 has previously been demonstrated to induce a unique LIYV cytopathology, plasmalemma deposits (PLDs), but no role is yet known for P9.     

The complete genomic sequence of <Emphasis Type="Italic">Tobacco vein banding mosaic virus</Emphasis> and its similarities with other potyviruses

The complete genomic sequence of an isolate of Tobacco vein banding mosaic virus (TVBMV-YND) from Yunnan, China was determined by sequencing overlapping cDNA fragments obtained by RT-PCR with degenerate and/or specific primers. The genome is composed of 9,570 nucleotides (nt) excluding the 3′-terminal poly (A) tail and contains one single open reading frame of 9,240 nt encoding a large polyprotein of 3,079 amino acids with predicted Mr of 348.6 kDa. Phylogenetic analysis of complete genomic sequences confirmed that TVBMV is a distinct species of the genus Potyvirus. Different parts of TVBMV-YND genome shared different levels of identity with other species of potyviruses, while most parts showed greatest identity with Chilli veinal mottle virus among the potyviruses with available complete genomic sequences. TVBMV-YND had a rare Q/N cleavage site for NIb/CP and uncommon RITC motif in HC-Pro that is crucial for aphid transmission of potyviruses. Xiao-Qing Yu and Yu-Fei Lan contributed equally to this research     

Identification of a Naturally Occurring Recombinant Isolate of <Emphasis Type="Italic">Sugarcane Mosaic Virus</Emphasis> Causing Maize Dwarf Mosaic Disease

The complete nucleotide sequence of a potyvirus causing severe maize dwarf mosaic disease in Shaanxi province, northwestern China was determined (GenBank accession No. AY569692). The full genome is 9596 nucleotides in length excluding the 3 -terminal poly (A) sequence. It contains a large open reading frame (ORF) flanked by a 149 nt 5-untranslated region (UTR) and a 255 nt 3-UTR. The putative polyprotein encoded by this large ORF comprises of 3063 amino acid residues. Sequence comparisons and phylogenetic analyses showed that this potyvirus is an isolate of Sugarcane mosaic virus (SCMV). The entire sequences shared identities of 89.6–97.6 % and 79.3–93.3% with 9 sequenced SCMV isolates at the nucleotide and deduced amino acid levels, respectively. But it showed much lower identities with Maize dwarf mosaic virus (MDMV), Sorghum mosaic virus (SrMV) and Johnsongrass mosaic virus (JGMV) isolates. The putative coat protein sequence is identical to that of a Chinese maize isolate SCMV-HZ. However, partition comparisons and phylogenetic profile analyses of the viral nucleotide sequences indicated that it is a recombinant isolate of SCMV. The recombination sites are located within the 6K1 and CI coding regions.     

The Complete Nucleotide Sequence of a Pakistani Isolate of Watermelon Mosaic Virus Provides Further Insights into the Taxonomic Status in the Bean Common Mosaic Virus Subgroup

Watermelon mosaic virus (WMV) is a potyvirus with a worldwide distribution, but is mostly found in temperate and Mediterranean regions. The complete nucleotide (nt) sequence of a Pakistani isolate of WMV (WMV-Pk) was determined and compared with French isolate (WMV-Fr) and other closely related potyviruses. WMV-Pk showed overall identities of 94.4% (nt) and 96% (amino acid; aa) with the WMV-Fr. However, variability was observed in the 5′ UTR and P1 region. Although sequence identities over most of the genome were well above 90% at both the nt and aa levels, reaching 99.6% (aa) in the CP and 100% (aa) in the 6K1 and 6K2, thereby suggesting that WMV-Pk and WMV-Fr are identical strains, but the sequence identities in the P1 region were only 80.6% (aa) and 82.8% (nt), while that in the 5′ UTR was 82%. These differences may be due to different mutation phenomena of a common ancestor virus or mutations caused by different selection pressures in two different agro-ecological zones. The sequence of WMV-Pk is very close to that of Soybean mosaic virus (SMV) over most of the genome, except for the N-terminal region, which is subject to recombination between SMV and Peanut stripe virus (PSV)/Bean common mosaic virus (BCMV), as revealed by Simplot and phylogenetic analyses of N- and C-terminal P1, HC-Pro, and 5′ UTR regions of the genome.     

The protruding domain of the coat protein of Melon necrotic spot virus is involved in compatibility with and transmission by the fungal vector Olpidium bornovanus

The Chi and W strains of Melon necrotic spot virus (MNSV) are efficiently transmitted by isolates Y1 and NW1, respectively, of the fungal vector Olpidium bornovanus. Analysis of chimeric viruses constructed by switching the coat protein (CP) gene between the two strains unveiled the involvement of the CP in the attachment of MNSV to zoospores of a compatible isolate of O. bornovanus and in the fungal transmission of the virus. Furthermore, analysis of the chimeric virus based on the Chi strain with the protruding domain of the CP from strain W suggested the involvement of the domain in compatibility with zoospore. Comparison of the three-dimensional structures between the CP of the two MNSV strains showed that many of the differences in these amino acid residues are present on the surface of the virus particles, suggesting that these affects the recognition of fungal vectors by the virus.     

Molecular characterization and evolutionary analysis of <Emphasis Type="Italic">soybean mosaic virus</Emphasis> infecting <Emphasis Type="Italic">Pinellia ternata</Emphasis> in China

Twenty-nine Pinellia ternata specimens were collected from representative areas in China, including the major production provinces of Zhejiang, Henan, Shanxi, Hunan, Shandong and Hubei. Seven isolates related to soybean mosaic virus (SMV), which could be pathogenic on P. ternata and some soybean [Glycine max (L.) Merr.] cultivars, were detected using double antibody sandwich immunosorbent assay (DAS-ELISA) and RT-PCR amplification performed with degenerate primer of potyviruses. It is revealed that the common potyvirus infecting P. ternata is, indeed, only SMVs rather than Dasheen mosaic virus (DsMV) as previously reported. Further molecular phylogenetic analysis of the coat protein (CP) genes of these SMV isolates from P. ternata and G. max, along with some other potyvirus members, such as DsMV and Watermelon mosaic virus (WMV) reconstructed the evolutionary route on both nucleotide and amino acid levels. Similarity and homology of nucleotide sequences for SMV CP genes demonstrated high host correlation and low partial habitat correlation, while those of amino acid sequences also showed that the host correlation was more notable than the habitat correlation. The amino acid sequence of conserved region within CP determines the main function, which shows high homology between species. This study outspreaded from the viruses themselves and their relationship to the infected hosts and revealed the evolutionary strategies, especially the rapid variation or recombination of SMV of P. ternata, in order to adapt itself naturally to the special host. The GenBank Accession numbers of the sequences reported in this article are DQ360817-DQ360823.     

Complete sequence of Fig fleck-associated virus, a novel member of the family Tymoviridae

The complete nucleotide sequence and the genome organization were determined of a novel virus, tentatively named Fig fleck-associated virus (FFkaV). The viral genome is a positive-sense, single-stranded RNA 7046 nucleotides in size excluding the 3′-terminal poly(A) tract, and comprising two open reading frames. ORF1 encodes a polypeptide of 2161 amino acids (p240), which contains the signatures of replication-associated proteins and the coat protein cistron (p24) at its 3′ end. ORF2 codes for a 461 amino acid protein (p50) identified as a putative movement proteins (MP). In phylogenetic trees constructed with sequences of the putative polymerase and CP proteins FFkaV consistently groups with members of the genus Maculavirus, family Tymoviridae. However, the genome organization diverges from that of the two completely sequenced maculaviruses, Grapevine fleck virus (GFkV) and Bombix mori Macula-like virus (BmMLV), as it exhibits a structure resembling that of Maize rayado fino virus (MRFV), the type species of the genus Marafivirus and of Olive latent virus 3 (OLV-3), an unclassified virus in the family Tymoviridae. FFkaV was found in field-grown figs from six Mediterranean countries with an incidence ranging from 15% to 25%.     

Transgenic expression of coat protein gene of <Emphasis Type="Italic">Rice tungro bacilliform virus</Emphasis> in rice reduces the accumulation of viral DNA in inoculated plants

Rice tungro, a devastating disease of rice in south and southeast Asia, is caused by the joint infection of Rice tungro bacilliform virus (RTBV) and Rice tungro spherical virus (RTSV). In order to obtain transgenic resistance against RTBV, indica rice cultivar Pusa Basmati-1 was transformed to express the coat protein (CP) gene of an Indian isolate of RTBV. Rice plants containing the transgene integrated in low copy numbers were obtained, in which the CP was shown to accumulate in the leaf tissue. The progenies representing three independent transformation events were challenged with Indian isolates of RTBV using viruliferous Green leafhoppers, and the viral titers in the inoculated plants were monitored using DNA dot-blot hybridization. As compared to non-transgenic controls, two independent transgenic lines showed significantly low levels of RTBV DNA, especially towards later stages of infection and a concomitant reduction of tungro symptoms. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Phylogenetic analysis of <Emphasis Type="Italic">Beet necrotic yellow vein virus</Emphasis> isolates from China

A survey detected Beet necrotic yellow vein virus (BNYVV) infection in six Chinese sugar-beet-growing regions. To study the diversity of virus isolates among the regions, nucleotide sequences of four proteins, namely CP, p25, p31, and p26, were determined and the amino acid sequences thus deduced were analyzed using sequence alignments and the phylogenetic method, respectively. Amino acid sequence analysis of CP revealed A-type isolates in Harbin, Hohhot, Baotou, Wuwei, and Jiuquan and B-type isolates in Hohhot and Changji; no Chinese isolate was found to cluster with European P-type isolates. Chinese p25 proteins clustered into three groups with seven tetrad motifs (positions 67–70). Of the seven, the tetrad ASHG has not been reported previously. Most Chinese p31 proteins clustered in p31-2 group, diverging from European p31 proteins. Isolates containing RNA 5 occurred in most of the investigated regions and were associated with both A-and B-types. Phylogenetic analyses of these four proteins showed complex patterns of genetic diversity among these Chinese isolates and indicated that the isolates of China and Japan were more closely related and may have a common origin. The nucleotide sequence data reported in this article have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers EF473089–EF473126.     

The complete genome sequence for a Turkish isolate of <Emphasis Type="Italic">Wheat dwarf virus</Emphasis> (WDV) from barley confirms the presence of two distinct WDV strains

The complete genome for a barley isolate of Wheat dwarf virus (WDV) from Tekirdağ, Turkey, WDV-Bar[TR], was isolated and sequenced. The genome was found to be 2739 nucleotides long, which is shorter than wheat-infecting WDV isolates, and with a genome organization typical for mastreviruses. The complete genome of WDV-Bar[TR] showed 83–84% nucleotide identity to wheat isolates of WDV, with the non-coding regions SIR and LIR least conserved (72–74% identity). The deduced amino acid sequences for Rep and RepA were most conserved (92–93%), while CP and MP were less conserved (87% and 79–80%, respectively). The identity to other mastrevirus species was significantly lower. In phylogenetic analyses, the WDV isolates formed a distinct clade, well separated from the other mastreviruses with the wheat isolates grouping closely together. Phylogenetic analyses of WDV-Bar[TR], the partial sequence for another Turkish barley isolate (WDV-Bar[TR2]) and published WDV sequences further supported the division of WDV into two distinct strains. The barley strain could also be divided into three subtypes based on relationships and geographic origin. This study shows the first complete published sequence for a barley isolate of WDV. The nucleotide sequence data reported appear in the EMBL, GenBank and DDBJ Nucleotide Sequence Databases under the accession numbers AJ783960 and AJ811960.     

Genetic structure and variability of virus populations in cross-protected grapevines superinfected by Grapevine fanleaf virus

Recombination was assessed in a vineyard site in which grapevines cross-protected with mild strains GHu of Grapevine fanleaf virus (GFLV) or Ta of Arabis mosaic virus (ArMV) were superinfected with GFLV field isolates following transmission by the nematode vector Xiphinema index. The genetic structure and variability within RNA2 of isolates from grapevines co-infected with GFLV field isolates and either GFLV-GHu or ArMV-Ta were characterized to identify intra- and interspecies recombinants. Sequence analysis and phylogenetic relationships inferred intraspecies recombination among GFLV field isolates but not between field isolates and GFLV-GHu. SISCAN analysis confirmed a mosaic structure for two GFLV field isolates for which recombination sites were located in the movement protein and coat protein genes. One of the recombinants was found in eight grapevines that were in close spatial proximity within the vineyard site, suggesting its transmission by X. index. No interspecies recombination was detected between GFLV field isolates and ArMV-Ta. Altogether, our findings suggest that mild protective strains GFLV-GHu and ArMV-Ta did not assist the emergence of viable recombinants to detectable level during a 12-year cross-protection trial. To our knowledge, this is the first extensive characterization of the genetic structure and variability of virus isolates in cross-protected plants.     

Comparisons of complete RNA-2 sequences,pathological and serological features among three Japanese isolates of <Emphasis Type="Italic">Arabis mosaic virus</Emphasis>

Arabis mosaic virus lily and narcissus isolates (ArMV-Li and ArMV-Na) induced severe necrotic spots on Chenopodium quinoa, whereas ArMV butterbur isolate (ArMV-Bu) caused symptomless infection in the plant. The accumulation level of ArMV-Bu in upper non-inoculated leaves of C. quinoa was comparable to that of ArMV-Li or -Na. The agar gel double-diffusion test using an antiserum against ArMV-Li showed ArMV-Li was closely related to ArMV-Na, but not to ArMV-Bu. The RNAs-2 of ArMV-Li, -Na, and -Bu consist of 3707, 3709, and 3789 nucleotides, and they contain one open reading frame encoding a putative polyprotein of 1083, 1084, and 1122 amino acids, respectively. The overall identity of RNA-2 of ArMV-Li displayed more than 90% with ArMV-Na, but less than 70% with ArMV-Bu. A phylogenetic analysis of 2A sequences from ArMV isolates revealed ArMV-Bu was not categorized in any cluster. ArMV-Bu is a unique isolate from the point of view of pathological and serological features, and nucleotide sequence.