Characterisation of full genome of Dolichos yellow mosaic virus based on sequence comparison,genetic recombination and phylogenetic relationship

Yellow mosaic disease (YMD) is one of the most important diseases affecting different leguminous crops and causes significant yield losses in Indian sub‐continent. Eight different bipartite begomovirus species are known to cause YMD in more than 10 leguminous crops. These species are collectively known as legume yellow mosaic viruses (LYMVs), and their full genomes have been characterised except for Dolichos yellow mosaic virus (DoYMV). In this study, full genome of DoYMV isolate (KJ481204 and KJ481205) infecting dolichos has been characterised. The DNA‐A of DoYMV consists of 2761 nucleotides and DNA‐B of 2733 nucleotides with a genome organisation typical of Old World bipartite begomoviruses. Nucleotide identity of DNA‐B (KJ481205) of DoYMV with DNA‐B of other legumoviruses was 57.5–61.0%. Both components contain a nonanucleotide and conserved inverted repeat sequences with the potential to form a stem‐loop. Nucleotide identity of common region of DoYMV was 90.3%, above the threshold nucleotide identity (>85%) for considering a DNA‐B molecule as cognate of DNA‐A of a begomovirus. Four recombination events in DNA‐A and two in DNA‐B of DoYMV isolate were detected. Mungbean yellow mosaic virus, Rhynchosia yellow mosaic virus and Horsegram yellow mosaic virus were identified as probable parents.     

Commonly conserved genetic fragments revealed by genome profiling can serve as tracers of evolution

We developed a method to produce, identify and analyze DNA fragments for the purpose of taxonomic classification. Genome profiling (GP) is a strategy that identifies genomic DNA fragments common to closely related species without prior knowledge of the DNA sequence. Random PCR, one of the key technologies of GP, is used to produce fragments and may be used even when there are mutations at the priming site. These fragments can then be distinguished based on the information of mobility and melting pattern when subjected to temperature gradient gel electrophoresis (TGGE). Corresponding fragments among several species, designated as commonly conserved genetic fragments (CCGFs), likely have the same genetic origin or correspond to the same gene. The criteria for identification of CCGFs has been defined and presented here. To assess this prediction, some of the fragments were sequenced and were confirmed to be CCGFs. We show that genome profiles bearing evolutionarily conserved CCGFs can be used to classify organisms and trace evolutionary pathways, among other profound applications.