Identification and use of a wild plant with antimicrobial activity against Ralstonia solanacearum, the cause of bacterial wilt of potato

Fresh aerial tissue and roots of 14 wild plants in Okinawa prefecture were investigated for their antimicrobial activity against Ralstonia solanacearum , which causes bacterial wilt of potato. A 70% aqueous ethanol extract of fresh aerial tissue of Geranium carolinianum L. showed strong antimicrobial activity against R. solanacearum . This extract also showed antimicrobial activity against the pathogens causing common scab of potato and soil rot of sweet potato. The antimicrobial substance could be extracted with hot water, and was effective against R. solanacearum in soil. In the field test, a treatment combining incorporation of dried aerial tissue into the soil and solarization was highly effective for control of bacterial wilt of potato. These findings suggest that G. carolinianum L. could be used as a biological agent for the control of bacterial wilt of potato.     

番茄青枯病植物疫苗胶悬菌剂的制备及其对病害的防治效果

研究了植物疫苗胶悬剂的制备工艺,确定胶悬剂制备的适宜参数为:琼脂终浓度为2.0‰、氯化钠终浓度为2.0%和pH为7.0。在此条件下,胶悬效果最好,质地均匀,无上下分层。试验了植物疫苗胶悬剂对番茄青枯病的防治效果,结果表明,该胶悬剂能较好地抑制番茄青枯病的发生,其防效(77.45%)与化学农药72%农用硫酸链霉素SP(77.23%)相当,配合生防菌剂20亿活芽孢/g蜡质芽孢杆菌WP施用,效果更佳,防效达81.81%。     

An improved enrichment broth for the sensitive detection of Ralstonia solanacearum (biovars 1 and 2A) in soil using DAS–ELISA

A reliable, sensitive, low-cost and easy-to-use technique is described for the detection of Ralstonia solanacearum (the causal organism of bacterial wilt, BW) in soil. A total of 273 potato isolates belonging to five different biovars (Bv), originating from 33 countries worldwide, were tested and successfully detected by antibodies produced at the International Potato Center (CIP). Isolates of R. solanacearum belonging to Bv1 and Bv2A were successfully detected by double antibody sandwich–enzyme-linked immunosorbent assay (DAS–ELISA) at low population levels after incubation of soil suspensions for 48 h at 30°C in a new semiselective broth containing a potato tuber infusion. Detection thresholds of 20 and 200 CFU g⁻¹ inoculated soil were obtained for Bv1 and Bv2A, respectively. Sensitivity of detection of Bv2A was similar or even higher in five different inoculated soil types. No cross-reactions were obtained in DAS–ELISA after enrichment of soil suspensions (i) prepared from 23 different soils sampled in BW-free areas in six departments of Peru; and (ii) inoculated with 10 identified bacteria and 136 unknown isolates of soil microbiota isolated from eight different locations. Only the blood disease bacterium gave a low-level reaction after enrichment. In naturally infested soils, average sensitivities of 97·6 (SE 14·8) and 100·9 (SE 22·6) CFU g⁻¹ were obtained for biovars 1 and 2A, respectively. By making serial dilutions of the soil suspension before enrichment, densities of R. solanacearum could be determined in a semiquantitative way. Results also showed that composite samples of five soils could be analysed to assess field soil populations without reducing detection sensitivity.     

The potential for using cyanobacteria (blue-green algae) and algae in the biological control of plant pathogenic bacteria and fungi

Cyanobacteria (blue-green algae) and eukaryote algae occur in freshwater, marine, and terrestrial (soil) habitats. In fact, these microorganisms comprise most of the world's biomass. Although the cyanobacteria are mostly photoautotrophic, some are facultative heterotrophs, capable of growing on certain substrates in darkness. Also, some are non-phototrophic and hence, are obligate heterotrophs. A number of cyanobacteria and eukaryote algae, particularly macroalgae, produce various, biologically active compounds. These include antibiotics which in laboratory tests inhibited bacteria and fungi that incite diseases of humans. In addition, the following fungi which are of interest to plant pathologists, were inhibitedin vitro by substances produced by various cyanobacteria: The saprophytesChaetomium globosum, Cunninghamella blakesleeana, andAspergillus oryzae and the plant pathogensRhizoctonia solani andSclerotinia sclerotiorum. Extracts from seaweeds (macroalgae) sprayed on plants have been reported to reduce the incidence ofBotrytis cinerea (gray mold) on strawberries,Erysiphe polygoni (powdery mildew) on turnips, and damping-off of tomato seedlings. Because many cyanobacteria and algae produce a large number of antibacterial and antifungal materials, are almost never a threat to the environment, and many can be grown in quantity in mass culture, they are suitable candidates for exploitation as biocontrol agents of plant pathogenic bacteria and fungi. Much additional work remains to be done however, to thoroughly evaluate cyanobacteria and algae and their products for this role.