Detection and identification of Xanthomonas campestris pv. campestris and pv. raphani by multiplex polymerase chain reaction using specific primers.

Black rot and bacterial spots threaten the cultivation of cruciferous vegetables worldwide, and the development of a method that can easily detect, identify, and distinguish their respective pathogens Xanthomonas campestris pv. campestris (Xcc) and X. campestris pv. raphani (Xcr) is required. Multiple whole-genome sequences of Xcc and Xcr were aligned to identify specific regions and subsequently design gene markers. A region present in Xcr, but absent in Xcc, was detected, which was approximately 11.5 kbp in length, sandwiched between the serine protease homolog (SPH) and nicotinate phosphoribosyltransferase gene (pncB). It contained putative cellulose synthesis-related genes, whereas Xcc only had a modified cellulose synthase gene. Designed primers were pncB_fw1 and pncB_fw2 (from the pncB gene), Xcc_rv1 and Xcc_rv2 (from the modified cellulose synthesis gene), and Xcr_rv1 and Xcr_rv2 (from the putative first and second open reading frames of the gene cluster). PCR using pncB_fw1 and Xcc_rv1, or pncB_fw2 and Xcc_rv2, amplified DNA fragments only in Xcc and X. campestris pv. incanae (Xci). Xci is the causal agent of black rot of garden stock and closely related to Xcc. PCR using pncB_fw1 and Xcr_rv1, or pncB_2 and Xcr_rv2, amplified DNA fragments only in Xcr. Multiplex PCR analysis easily distinguished Xcc and Xcr from bacterial colonies isolated on growth media and detected the pathogen in symptomatic leaves. Multiplex nested PCR detected the contamination of one seed with Xcc and/or Xcr infection from 1000 seeds. Therefore, the PCR primers designed in this study therefore helped detect and discriminate between Xcc and Xcr. KEY POINTS: • Xanthomonas campestris pv. campestris (Xcc) and pv. raphani (Xcr) were investigated. • Novel primers were designed following whole-genome comparison analyses. • Multiplex PCR with new primers distinguished Xcc and Xcr simultaneously.