Further support of genetic conservation in Indian isolates of Rice tungro bacilliform virus by sequence analysis of an isolate from North-Western India.

The genomic sequence of an isolate of Rice tungro bacilliform virus (RTBV), collected from the state of Punjab (Pb), a non-endemic tungro region from North-Western India was determined. In silico comparison of the 7931-bp sequence with isolates from Southeast Asia and the three previously characterized Indian isolates, revealed not only similar genome size to other Indian isolates but also high degree of homology both at nucleotide (>93 %) and amino acid (>96 %) levels among them. On the other hand, like the other Indian isolates, RTBV-Pb showed much lower nucleotide (<87 %) and amino acid (<90 % in most of the open reading frames) identities with the Southeast Asian isolates owing to several nucleotide substitutions and indels. In-depth annotation comparisons reinforce the hypothesis that Indian isolates of RTBV have diverged sufficiently from the Southeast Asian ones to form a separate group.

The molecular diversity and evolution of Rice tungro bacilliform virus from Indian perspective.

Rice tungro disease is caused by a combination of two viruses: Rice tungro spherical virus and Rice tungro bacilliform virus (RTBV). This study was performed with the objective to decipher the molecular variability and evolution of RTBV isolates present in the tungro-affected states of Indian subcontinent. Phylogenetic analysis based on ORF-I, ORF-II, and ORF-IV sequences showed distinct divergence of Indian RTBV isolates into two groups; one consisted isolates from Hyderabad (Andhra Pradesh), Cuttack (Orissa), and Puducherry and another from West Bengal, Chinsura West Bengal, and Kanyakumari (Tamil Nadu). The results obtained from phylogenetic analysis were further supported with the single nucleotide polymorphisms (SNPs), insertion and deletion (INDELs) and evolutionary distance analysis. In addition, sequence difference count matrix revealed a maximum of 56 (ORF-I), 13 (ORF-II) and 73 (ORF-IV) nucleotides differences among all the Indian RTBV isolates taken in this study. However, at the protein level these differences were not significant as revealed by K (a)/K (s) ratio calculation. Sequence identity at nucleotide and amino acid level was 92-100 % (ORF-I), 96-100 % (ORF-II), 94-100 % (ORF-IV) and 86-100 % (ORF-I), 98-100 % (ORF-II) and 95-100 % (ORF-IV), respectively, among Indian isolates of RTBV. The divergence of RTBV isolates into two independent clusters of Indian and non-Indian was shown with the help of the data obtained from phylogeny, SNPs, and INDELs, evolutionary distance analysis, and conserved motifs analysis. The important role of ORF-I and ORF-IV in RTBV diversification and adaptation to different rice growing regions is also discussed.

Analysis of the complete DNA sequence of rice tungro bacilliform virus from southern India indicates it to be a product of recombination.

The complete nucleotide sequence of an isolate of rice tungro bacilliform virus (RTBV), collected from Kanyakumari, India, where RTBV was reported recently for the first time, has been analyzed. Sequence comparison revealed that the RTBV isolate from Kanyakumari (RTBV-KK) has a high degree of identity to the two previously reported RTBV sequences from India, RTBV-AP and RTBV-WB, which had been collected from field locations about 10 years ago and 1000-2000 km away from the collection site of RTBV-KK. Most of the sequence domains reported previously in other RTBV isolates were found to be conserved in RTBV-KK. Closer inspection revealed RTBV-KK to be a possible recombinant between RTBV-AP and RTBV-WB in the genomic region encompassing the coat protein gene.

Phylogenetic analysis of Rice tungro bacilliform virus ORFs revealed strong correlation between evolution and geographical distribution.

A new isolate of Rice tungro bacilliform virus (RTBV) was collected from Chinsura, West Bengal, India. The full genome was sequenced and deposited to GenBank designating the new one as Chinsura isolate. The four open reading frames (ORFs) of the new isolate were compared with those of previously reported 'South-east Asian' (SEA) and 'South Asian' (SA) isolates emphasizing the ORF3, which is the largest and functionally most important gene of RTBV. In the ORFs, Chinsura isolate shared 90.0-100.0% identity at amino acid level with SA isolates, but only 58.76-88.63% identity with SEA isolates for the same. Similarly, the amino acid identity of ORFs between SEA and SA isolates ranged from 58.77 to 88.64, whereas within each group the corresponding value was >96.0%. The phylogenetic analysis based on nucleotide and amino acid sequences of each ORF made two broad clusters of SEA- and SA-types including Chinsura isolate within SA cluster. Moreover, the relative positions and length of functional domains corresponding to movement protein (MP), coat protein (CP), aspartate protease (PR) and reverse transcriptase/ribonuclease H (RT/RNase H) of ORF3 of Chinsura isolate were completely identical with SA isolates. The clustering pattern indicated strong influence of geographical habitat on genomic evolution. Comparison of ORF3 among all the isolates revealed major variations at non-functional regions in between the functional domains and at the hypervariable 3'-terminal end of ORF3, while PR appeared to have evolved differentially in SA isolates expecting further characterization.