Hirofumi Nagai

Monitoring by real-time PCR of three water-borne zoosporic Pythium species in potted flower and tomato greenhouses under hydroponic culture systems

The high-temperature-tolerant Pythium species P. aphanidermatum, P. helicoides, and P. myriotylum cause serious diseases in many crops under hydroponic culture systems in Japan. Control of the diseases is difficult because these zoosporic pathogens spread quickly. In this study, a real-time PCR method was developed for monitoring the spread of zoospores of the three pathogens. Specific primers and TaqMan probes were established using the internal transcribed spacer regions of the rDNA. Specificity was confirmed using known isolates of each species and closely related non-target species. The sensitivity of DNA detection was 10 f. for each pathogen. 10 f. DNA corresponded to 4 P. aphanidermatum, 3 P. myriotylum, and 4 P. helicoides zoospores, respectively. Therefore, this real-time PCR method was used to evaluate and monitor zoospores in the nutrient solutions of ebb-and-flow irrigation systems for potted flower production and closed hydroponic culture systems for tomato production. The results indicated that the pathogens were present in the hydroponic culture systems throughout the year, and spread before disease occurrence.

Practical method combining loop-mediated isothermal amplification and bait trap to detect Pythium helicoides from hydroponic culture solutions

Two detection methods combining loop-mediated isothermal amplification (LAMP) and a bait trap were developed to detect Pythium helicoides in greenhouses containing roses, miniature roses, and poinsettias in hydroponic culture systems. In “Bait-LAMP”, a crude extract derived from perilla seeds as the bait was used in the LAMP reaction, whereas in the “Bait culture-LAMP”, a crude extract of mycelia grown out from perilla seeds onto Pythium-selective medium served as the bait. The two methods are simple and rapid for practical monitoring of P. helicoides in hydroponic culture systems.

Improved control of black rot of broccoli caused by Xanthomonas campestris pv. campestris using a bacteriophage and a nonpathogenic Xanthomonas sp. strain

We examined the potential for biological control of black rot of broccoli, caused by Xanthomonas campestris pv. campestris (Xcc), using nonpathogenic Xanthomonas sp. strain 11-100-01 (npX) mixed with bacteriophage XcpSFC211 (pXS). Inoculation of intact broccoli plants in greenhouse trials with either npX or pXS did not control black rot. After injured plant inoculation, however, npX alone or npX with pXS significantly controlled black rot. When a mixed suspension of npX with pXS was placed on a membrane filter, then washed with distilled water and air-dried, a substantial amount of pXS adsorbed to the surface of npX. In a field trial, broccoli plants were sprayed with a suspension of npX with pXS, then inoculated with Xcc. A meta-analysis of the results from five field trials showed an integrated risk ratio (IRR, the ratio of disease incidence in inoculated broccoli plants to the incidence in control plants) of 0.69 after treatment with only npX and 0.59 with npX with pXS, indicating that black rot incidence was significantly reduced by each treatment. The difference between these two treatments was also significant. IRR was 1.24 when comparing suppression by npX with pXS and that by basic copper sulfate wettable powder; thus, their control was comparable. The combination of npX with pXS improved the preventive effect against black rot. This is the first report describing that a nonpathogenic Xanthomonas sp. strain mixed with a bacteriophage effectively controlled black rot of broccoli in field trials.