Ralstonia solanacearum1,2 formally known as Pseudomonas solanacearum and Burkholderia solanacearum is a gram-negative, chemo-organotroph phytopathogenic β-proteobacterium with an unusual broad host range.3 The pathogen not only affects solanaceous but many plants of other dicot and monocot families. The extensive genetic diversity of strains responsible for various wilt diseases has in recent years led to the concept of an R. solanacearum “species complex” (RsSC).4 As R. solanacearum strains have been isolated from virgin forest-soils of all five continents, the origin of the species complex is believed to predate the geographical separation of continents.5 The pathogen is hierarchically classified into four phylotypes according to newly proposed phylotype sub-classification system based on 16S-23S ITS region, egl and hrpB genes and on comparative genomic hybridization (CGH) which reflect their origin as Asia (Phylotype I), America (II), Africa (III) or Indonesia (IV).6 These phylotypes are further classified into sequevars, containing isolates with similar virulence patterns or common geographic origin.3 Despite their considerable diversity, R. solanacearum strains are unified by their common etiology resulting in disease.7 Three of the four phylotypes of R. solanacearum are known to cause bacterial wilt of potato in India.8 In the present study four strains, RS2 (Phylotype II), RS25 and RS48 (Phylotype I) and RS75 (Phylotype IV) isolated from brown-rot infected potato tubers obtained from different parts of the country were taken for complete genome sequencing and to analyze their relationship complexity.

We sequenced the genomes of all four strains using shotgun approach and Roche-454, GSflx-Titanium platform yielding appx. 2.88 million reads (>500bp) of which nearly 99.5% reads were of high quality. The genome coverage ranged from 18X (RS48) to 76X (RS75). The high quality reads were aligned using GS De Novo Assembler (version 2.5.3) and gene prediction using the prokaryotic GeneMark.hmm (Version 2.2a) and AUGUSTUS (http://bioinf.uni-greifswald.de/augustus/submission/) revealed a total of 4590, 4732, 4817 and 4867 protein coding regions (CDSs) respectively for RS2, RS25, RS48 and RS75 spread over megaplasmid as well as chromosomal genomes. High quality reads were mapped on to publically available reference genomes, GMI1000 (RS25 & RS48), Po82 (RS2) and PSI07 (RS75) (www.ncbi.nlm.nih.gov/genome/) using gsMapper with optimized mapping parameters and obtained total genome coverage and per cent GC content for all four strains. The total protein coding regions, rRNA and tRNA coding, regulatory and pathogenicity genes including the Type III secretary genes were obtained from the consensus using the .gff (from public database) file with the help of in-house perl scripts (Table 1). The presence of repetitive elements was analyzed using MISA (http://pgrc.ipk-gatersleben.de/misa/) and was observed that nearly 90% of the elements were of di or tri and 7.3% hexa mer repeats. Chromosomes carried higher portion (60–70%) of the repeat elements than megaplsmids in all the four strains. The availability of the reference genomes of more and more strains of RsSC would greatly aid in epidemiological/quarantine studies and in gaining understanding on their origin, evolution, intra and inter-relationship within the complex and their interactions with plants.

Nucleotide sequence accession numbers. This Whole Genome Shotgun project has been deposited at NCBI/GenBank under Bio-Project PRJNA221562 with Accession Nos. SRX360515, SRX365373, SRX365374 and SRX365375.

The authors declare no conflicts of interest.