Phylogenetic analysis of coat protein gene of BYDV-MAV strain from wheat

Barley yellow dwarf disease is globally the most important viral disease of wheat. The full-length nucleotide sequence of coat protein (CP) gene of 12 isolates revealed the presence of three distinct clusters. Pakistani isolate of MAV (MAV-PK) has maximum similarity of 99.23% with MAV isolate of Morocco and PAV-Australia following 99.22 and 99.22% with PAV-France. Similar degree of similarity was found in comparison of amino acid sequence. The finding of this study is that MAV-PK has similarity with both MAV-France and PAV-Australia, which is due to the reason that both MAV and PAV belong to the same group and both share maximum nucleotide homology. Low genetic diversity was found not only between MAV isolates but also between MAV and PAV isolates because phylogenetic analysis was done on the CP gene which is highly conserved region in genome of Barley yellow dwarf viruses (BYDVs). Divergence in MAV-PK was due to this recombination which is now most prevalent in Pakistan. MAV-PK has maximum similarity with MAV-Morocco followed by MAV-Sweden and MAV-Cz, which seems to indicate that Pakistani isolate of MAV evolved as the result of recombination between MAV isolates of the USA and PAV isolates of Australia and France. At the same time, recombination of MAV-CZ and MAV-Sweden also occur. This work can be successfully utilised in epidemiological studies of MAV isolate in Pakistan. Further analysis of variation level in these isolates will help scientists to formulate appropriate management strategies like incorporation of BdV 2 gene in wheat against BYDVs.     

Nucleotide sequence of coat protein gene for GPV isolate of barley yellow dwarf virus and construction of expression plasmid for plant

GPV is a Chinese serotype isolate of barley yellow dwarf virus (BYDV) that has no reactionwith antiserum of MAV, PAV, SGV, RPV and RMV. The sequence of the coat protein (CP) of GPV isolate of BYDV was identified and its amino acid sequence was deduced. The coding region for the putative GPV CP is 603 bases nucleotides and encodes a Mr 22218 (22 ku) protein. The same as MAV, PAV and RPV, GPV contained a second ORF within the coat protein coding region. This protein of 17024 Mr (17 ku) is thought to correspond to the Virion protein genome linked (Vpg). Sequence comparisons of the CP coding region between the GPV isolate of BYDV and other isolates of BYDV have been done. The nucleotide and ammo acid sequence homology of GPV has a greater identity to the sequence of RPV than those of PAV and MAV. The GPV CP sequence shared 83.7% of nucleotide similarity and 77.5% of deduced amino add similarity, whereas that of the PAV and MAV shared 56.9%. 53.2% and 44.1%. 43.8% respectively. According to BYDV-GPV CP seque     

Cloning and Phylogenetic Analysis of Coat Protein of Barley yellow dwarf virus Isolates from Different Regions of Pakistan

Barley yellow dwarf virus (BYDVs) is an emerging threat for wheat and may seriously threaten its production, especially as climate change may result in increased infestation by aphids, the insect vectors of the virus. To assess the possibility of using pathogen‐derived resistance against the virus, the genetic diversity of BYDVs originating from different wheat‐growing areas of Pakistan where its incidence has been higher was investigated. Wheat samples with suspected symptoms of BYDVs were screened for the presence of Barley yellow dwarf and Cereal yellow dwarf viruses (B/CYDVs) subgroup 1 (Barley yellow dwarf virus‐PAV, BYDV‐MAV, BYDV‐SGV) and subgroup II (BYDV‐RPV, CYDV‐RPV, BYDV‐GPV) by PCR using basic multiplex oligonucleotides designed on coat protein (CP) of the virus. Of 37 samples tested, 13 were positive for BYDV subgroup I and only one sample was positive for BYDV subgroup II. Samples positive for subgroup I were further tested by PCR, and results showed that 10 samples were positive for BYDV‐PAV and three for BYDV‐MAV. DNA sequences of CP region of nine isolates (BYDV‐PAV) were determined and compared with available sequences in databases. Sequence analysis showed that three isolates (from Fatehjang, Nowshera and Attock districts) had maximum identity (92.8–94.6%) to BYDV‐PAS, and six isolates (from Peshawar, Islamabad Swabi and Faisalabad districts) had maximum identity (99.3–99.7%) to BYDV‐PAV. Thus BYDV‐PAV species may be dominant in northern wheat‐growing areas of Pakistan. The conserved nature of the BYDVs suggests that pathogen‐derived resistance strategies targeting the coat protein of the virus are likely to provide protection under field conditions.     

Distribution of Cereal Luteoviruses and Molecular Diversity of BYDV‐PAV Isolates in Central and Southern Iran: Proposal of a New Species in the Genus Luteovirus

During a survey , 148 wheat, 70 barley and 24 wild grass samples of plants showing symptoms of yellowing or reddening of leaves and general stunting were collected in central and southern provinces of Iran and tested for Barley yellow dwarf virus (BYDV) and Cereal yellow dwarf virus (CYDV) infection by enzyme‐linked immunosorbent assay (ELISA) and tissue print immunoassay (TPIA). The results showed the presence of the viruses in most regions. Positive reactions to BYDV‐PAV, BYDV‐MAV, CYDV‐RPV and BYDV‐SGV antisera were recorded. BYDV‐PAV was the most prevalent virus. The genetic diversity of BYDV‐PAV isolates in central and southern provinces was studied by analysing ORF1 (903 nt) and read through domain (RTD) (575 nt) of 13 and nine isolates respectively. Sequence analysis of RTD at nucleotide and amino acid levels revealed a high identity (91.8–97.2% and 91.4–100% respectively) between Iranian and other available isolates in the GenBank. However, in regards to ORF1, a high genetic diversity among Iranian and other known PAV isolates at both amino acid (2–16.9%) and nucleotide (4.1–16.5%) levels were detected. Based on phylogenetic analysis of ORF1, two major groups of BYDV‐PAV isolates were distinguished. The Iranian isolates were divided between the two clusters. Our results suggest that the occurrence of two genetically distinct groups of PAV isolates in central and southern Iran, from which according to the ICTV criteria for species demarcation in the family Luteoviridae, four isolates from central parts of the country, qualify for designation as new species.     

香蕉束顶病毒基因克隆和序列分析

对香蕉束顶病毒（ＢＢＴＶ）中国分离株ＤＮＡ组份Ｉ（ＤＮＡ－１）、外壳蛋白（ＣＰ）和运转蛋白（ＭＰ）基因进行了克隆和序列分析。ＢＢＴＶＤＮＡ－１含有１１０３个核苷酸,与南太平洋和亚洲分离株分别有８７％－８８％ ９６．９－９８％的核苷酸序列同源性。由ＤＮＡ－１编码的复制酶含有１８６个在酸残基。与南太平洋和亚洲分离株分别有８４．４％－９５．８％和９７．６％、９８．０％的氨基酸序列同源性。外壳蛋白基因由５     

Konjac mosaic virus Naturally Infecting Three Aroid Plant Species in Andhra Pradesh,India

The genomes of three potyvirus isolates from, respectively, naturally infected Colocasia esculenta, Caladium spp. and Dieffenbachia spp. in Andhra Pradesh, India, were amplified by RT‐PCR using degenerate potyvirus primers. Sequence analysis of RT‐PCR amplicons (1599 nucleotides) showed maximum identity of 97% with the KoMV‐Zan isolate of Konjac mosaic virus (KoMV) from Taiwan (A/C AF332872). The three isolates had a maximum identity of 99.4%. The length of coat protein (CP) gene of three isolates was 846 nucleotides encoding 282 amino acids with a deduced size of 32.25 kDa. The CP gene of the isolates had, respectively, 78.1–95.7% and 88.2–96.4% identity at nucleotide and amino acid levels with KoMV isolates. The CP gene of the three isolates had 93.1–100% (nucleotide) and 98.2–100% (amino acid) identity. The 3′‐UTR of the three isolates showed maximum identity of 91.1–100% identity between and with other KoMV isolates. In the CP amino acid–based phylogenetic analyses, the isolates branched as a distinct cluster along with known KoMV isolates. The three potyvirus isolates associated with mosaic, chlorotic feathery mottling, chlorotic spots, leaf deformation and chlorotic ring spots on three aroids were identified as isolates of KoMV for the first time from Andhra Pradesh, India.     

Book Review

To study the variability and to identify the species of Begomovirus associated with yellow mosaic disease of blackgram in Andhra Pradesh, India, infected blackgram samples were collected from six districts belonging to three regions of Andhra Pradesh. The total DNA was isolated by modified CTAB method and amplified with coat protein gene-specific primers (RHA-F and AC abut) resulting in 900?bp gene product. The PCR products were cloned, sequenced and deposited in GenBank. The sequence analysis of six clones showed that the size of amplified CP gene of YMV was 920?bp. Based on nucleotide sequence identity of six isolates representing three regions of Andhra Pradesh, the isolates from Rayalaseema and Telangana region are the same variant of YMV (>99.5% identity) and isolate from coastal Andhra is another variant of YMV (>95.4%) when compared with other region isolates. Comparison of CP gene sequence of YMV-TPT isolate with 27 other isolates in database revealed more than 93.2 and 86.2% identity with MYMIV isolates and less than 80 and 64% identity with MYMY isolates that originate from Indian sub-continent and South-East Asia at nucleotide and amino acid level, respectively. Phylogenetic tree based on CP gene sequences of six isolates with other isolates from GenBank formed unique cluster with MYMIV. Hence the YMV infecting blackgram in Andhra Pradesh is caused by MYMIV rather than MYMY as reported in Tamil Nadu which is adjoining state in southern India.     

Incidence and genetic diversity of raspberry bushy dwarf virus (RBDV) in Rubus spp. in Turkey

Raspberry bushy dwarf virus (RBDV), recently renamed to Idaeovirus rubi, is one of the most common viruses infecting Rubus species worldwide but there is still a limited number of genome sequences available in the GenBank database and the majority of the sequences include partial sequences of RNA-1 and RNA-2. The distribution and incidence of RBDV in main raspberry and blackberry growing provinces in Turkey were monitored during 2015–2019 and 537 Rubus spp. samples were tested by both DAS-ELISA and RT-PCR. Among the tested samples, 36 samples tested positive for RBDV by DAS-ELISA and 67 samples by RT-PCR. There was relatively low nucleotide diversity among the Turkish isolates. Turkish isolates shared 93%–97.7%, 84.3%–98.9%, and 85%–99.2% nucleotide sequence identities with available sequences in the GenBank, in partial RNA-1, movement protein (MP) and coat protein (CP) genes, respectively. In the phylogenetic tree constructed for RNA-1, MP, and CP sequences, all Turkish raspberry isolates were clustered in a distinct clade. However, the blackberry isolates showed considerable variation in nucleotide sequences and were placed in three distinct groups. The divergent blackberry isolates showed high variability in MP (84.5%–89.3%) and CP (85.5%–89.7%) regions and were placed in a distinct group. The rest of blackberry isolates clustered together with sweet cherry RBDV isolates adjacent to the grapevine clade or together with raspberry isolates. The comparative analysis conducted on three RNA segments of RBDV highlighted the high sequence diversity of Turkish RBDV isolates. This study also emphasizes the importance of regular monitoring of RBDV infections in Turkey, with special regard to those Rubus spp. and grapevine accessions employed in conservation and selection programmes. In particular, the presence of new RBDV genetic variants and infection of Rubus species must be taken into account to choose a correct detection protocol and management strategy.     

Further Evidence for Limited Genetic Diversity among East African Isolates of Sweet potato chlorotic stunt virus

In Africa, the crinivirus Sweet potato chlorotic stunt virus (SPCSV) exists in two serologically and genetically distinct strains, geographically distinguished as a West African (SPCSV_WA) and an East African (SPCSV_EA) strain. To obtain a better understanding of the genetic diversity among SPCSV_EA isolates, the major coat protein (CP) and heat shock protein 70 homologue (Hsp70h) gene sequences of 24 further isolates of SPCSV_EA were determined and compared. SPCSV_EA diversity was also examined using available monoclonal antibodies (mAbs) to SPCSV_EA but there was no apparent coincidence between CP and partial Hsp70h gene nucleotide sequences and the subdivision of SPCSV_EA isolates by the mAbs into two serotypes, suggesting this latter may not be of great biological significance. The nucleotide (nt) sequences of isolates of SPCSV_EA displayed a high degree of conservation and the only variation observed consisted of a few base exchanges. Pairwise alignments of CP nucleotide sequences revealed differences of <4% between SPCSV_EA isolates. Comparisons with published SPCSV sequences confirmed a more distant relationship (up to 34.6% nt; 12% amino acid divergence) between the Hsp70h sequences of isolates of SPCSV_EA and SPCSV_WA and indicated that SPCSV_EA in East and Southern Africa is the more homogeneous than SPCSV_WA isolates from West Africa, North and South America, which were up to 12.4% nt divergent among themselves.     

Low Genetic Diversity of the Coat Protein Gene among Blueberry Red Ringspot Virus Isolates

Blueberry red ringspot virus (BRRSV) isolates have been investigated for genetic diversity. Nucleotide sequences of the coat protein (CP) gene of 19 isolates from Poland, Czech Republic, Slovenia and the United States were analysed. The nucleotide and amino acid sequence identity were 92–100% and 89–100%, respectively. Estimations of the distribution of synonymous and non‐synonymous changes indicated negative selection within the analysed CP gene and confirmed the genetic stability of the virus. At a capsid protein level, our results revealed BRRSV to be distinct from other, recombination‐prone pararetroviruses.     

Coat Protein Gene of Cymbidium mosaic virus from Vanilla fragrans in Reunion Island

Nucleotide and amino acid sequences of the coat protein (CP) of 12 isolates of Cymbidium mosaic virus from Vanilla fragrans in Reunion Island (CyMV‐R) were compared with each other and with those of previously described Asian strains. Alignment revealed that CyMV‐R isolates were highly homologous, suggesting that one strain is prevalent in Reunion. This strain also showed high homology with the Korean CyMV‐K2 and Singapore CyMV‐S2 strains, but nucleotide additions resulted in the carboxy‐terminal ends of the CP sequences differing from those of the Korean CyMV‐K1 and Singapore CyMV‐K1 strains.     

Biological and molecular characterisation of Prunus necrotic ringspot virus isolates and possible approaches to their phylogenetic typing

Seven isolates of Prunus necrotic ringspot virus (PNRSV) originating from Slovakia were subjected to biological tests under glasshouse conditions. Mainly mild symptoms were observed on chip‐budded test cherry rootstocks. The complete sequence for the capsid protein (CP) gene of four isolates was determined. All sequences were 675 nucleotides long and clustered in the largest of four groups delineated by phylogenetic analyses of all so far known PNRSV CP sequences. A set of restriction endonucleases was suggested to differentiate four isolate clusters by restriction enzyme digestion of CP sequences.     

Variation in the Coat Protein Gene of Papaya ringspot Virus Isolates from Multiple Locations of China

The potyvirus Papaya ringspot virus （PRSV） is an important pathogen of papaya that causes severe losses in economic crops for papaya production globally. The coat protein （CP） genes of five PRSV isolates originating from different locations in China were cloned and sequenced. The CP-coding region varied in size from 864-873 nucleotides, encoding proteins of 288-291 amino acids. The five Chinese isolates of PRSV have been characterized as papaya-infecting （PRSV-P）. The CP sequences of the Chinese isolates were compared with those of previously published PRSV isolates originating from different countries at amino acid levels. A number of KE repeat boxes in the N terminus of the PRSV-CP were found in all Chinese isolates. The phylogenetic branching pattern revealed that there was certain extended grouping between geographic locations, and the Asian type probably represents the oldest population of PRSV. The information of CP genes will be useful in designing and developing durable virus resistant-PRSV transgenic papaya in China. Meanwhile broad-spectrum-virus resistant, strongly resistant-PRSV and good safe papaya lines are required.     

马铃薯X病毒湖南分离物的鉴定与分组研究

从湖南石门采集表现重花叶症状的马铃薯叶片中分离纯化到一株线状病毒HN021。经双链RNA(ds—RNA)抽提、寄主反应测定、病毒粒子和内含体的形状观察,初步确定该病毒为马铃薯X病毒(Potato virus X)。以ds—RNA作为模板,用相应引物对HN021分离物的ORF4-UTR-ORF5片段进行RT—PCRP得到1kb左右的双链cDNA片段。对该片段进行克隆和测序,并将测序所得的核苷酸序列与Genbank(登录的11株不同分离物的相应片段的核苷酸序列进行同源性比较和分析。结果表明,HN021与分离自南美洲的三株分离物(COAT,KPA和HB)的同源性为78．4％—79．4％,与其它8株(分离自亚洲、欧洲、大洋洲和北美洲)分离物的同源性为96．4％—97．8％。从氨基酸水平比较,HN021与COAT,KPA和HB三者CP和8kDa蛋白氨基酸序列同源性分别为86．5％—89．0％和74．3％—75．7％,相应地与其它8株分离物的同源性分别为97．1％—98．7％和97．1％—100％。序列分析的结果证实了HN021分离物为马铃薯X病毒,同时表明PVX明显存在两个组(组Ⅰ和组Ⅱ),HN021和其它来自亚洲、欧洲、大洋洲、北美洲分离物的组Ⅱ,3个南美洲分离物属于组Ⅰ。     

Nucleotide sequence analysis of the 3'-terminal region of two Korean isolates of lily symptomless Carlavirus and expression of the coat protein in E. coli.

The 3'-terminal regions of the genomic RNAs of two Korean isolates of the lily symptomless Carlavirus (LSV), LSV-Ko and LSV-KII, were cloned and their nucleotide sequences were determined. The nucleotide sequence analysis and protein analysis by the Western blot revealed that E. coli expressed a 32-kDa protein that is the viral coat protein (CP) for the LSV. The two Korean strains share 98.4% and 98.3% sequence identities at the nucleotide and amino acid levels, respectively. The CP gene of LSV-Ko showed 99.1% and 87.0% nucleotide sequence identities, and 99.0% and 96.6% amino acid sequence identities with those of the Netherlands and the Japanese LSV strains, respectively. A pairwise amino acid sequence comparison revealed a sequence similarity of 29.6% to 69.8% between LSV-Ko and other species of the carlavirus. The 16 kDa protein of LSV-Ko shares 17.6% to 42.7% amino acid similarity with those of 8 other the carlaviruses, and they are variable in the N-terminal region. The Cys repeated zinc finger nucleic acid binding domain was found in the 16 kDa protein for all of the LSV strains. Sequence comparisons of the 7 kDa protein of LSV in the strain level showed significant identities from 100.0% to 98.4%. LSV-Ko shares 21.9% to 42.2% amino acid similarity with those of 8 other carlaviruses, 4 members of the potexviruses, and a closterovirus. LSV is closely related to blueberry scorch virus (BISV) based upon the phylogenetic tree analyses of the three proteins, indicating LSV to be a quite distinct member of the genus Carlavirus.