• Research in Plant Disease
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• v.9 no.2
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• pp.94-98
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• 2003

To produce antibodies against Pseudomonas tolaasii and P. agarici, lyophilized P. tolaasii and P. agarici ($5{\times}10^7$ cfu/ml) and Freund, s adjuvant were immunized into rabbits 4 times. The specificity and sensitivity of the antibodies were evaluated by immunodiffusion test and indirect enzyme-linked immunosorbent assay (id ELISA). The ${\alpha}$-P. tolaasii antibody was very specific only against P. tolaasii, while ${\alpha}$-P. agarici antibody was not specific and showed a high cross reactivity toward P. tolaasii with detection limit concentration of $2{\times}10^3$ cfu/ml. However, the cross reactivities of ${\alpha}$-P. agarici antibody toward the related species including P. reactans were very low. Our results showed that ${\alpha}$-P. tolaasii and ${\alpha}$-P. agarici antibodies against P. tolaasii and P. agarici, respectively, might be useful for rapid and simple detection of the causal agents of bacterial brown and yellow blotches in cultivated oyster mushrooms.

• Journal of Applied Biological Chemistry
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• v.61 no.4
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• pp.405-410
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• 2018

Pseudomonas tolaasii strain No. 6264 has been isolated from mushroom tissue and identified as one of the major pathogen causing brown blotch disease. It secretes peptide toxins, known as tolaasin and its analogue peptides. P. tolaasii 6264 has been used as a typical pathogenic strain to study the brown blotch disease for last 20 years after confirming its blotch-forming ability, hemolytic activity, and white line formation. In this study, the characteristics of P. tolaasii 6264 strain were analyzed and compared according to storage period. Strains of P. tolaasii 6264 stored annually since 2012 were cultured and their pathogenic characters were analyzed. When the 16S rRNA sequences were compared, all strains were divided into two groups. Pathogenic characters including hemolytic activity, blotch-forming ability, and white line test were also investigated. The strains, P. tolaasii 6264-15-2 and P. tolaasii 6264-17, had all three activities; however, the rest of stored strains showed only blotch-forming ability losing other pathogenic characters. Tolaasin peptides were purified from the bacterial cultures and analyzed by mass spectrometry. The strains, P. tolaasii 6264-15-2 and P. tolaasii 6264-17, secreted Tol I (1987 Da), Tol II (1943 Da), and its analogues (1973 Da, 2005 Da) while some of these peptides were not found in the media cultured other strains. These results indicate that the pathogenicity of P. tolaasii could be varied during the storage period.

• Korean Journal Plant Pathology
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• v.14 no.2
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• pp.177-183
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• 1998

A DNA fragment which is involved in tolassin production was cloned to obtain a molecular marker of Pseudomonas tolaasii, a casual agent of bacterial brown blotch disease of oyster mushroom (Pleurotus ostreatus). Tolaasin is a lipodepsipeptide toxin and known as a primary disease determinant of the P. tolaasii. It is responsible for formation of white line in agar when P. tolaasii were cultured against white line reacting organisms (WLROs). White line negative mutants (WL-) were generated by conjugation between rifampicin resistant strain of P. tolaasii and E. coli carrying suicidal plasmid pSUP2021 : : Tn5. The ability of tolaasin production of the WL- mutants was examined by hemolysis test, pathogenicity test, and high pressure liquid chromatography (HPLC) analysis of culture filtrate. All of the WL- mutants were lost the ability of tolaasin production (Tol-). Genomic library of the Tol- mutant was constructed in pLAFR3 and the cosmid clone containing Tn5 was selected. DNA fragment fro franking region of Tn5 was cloned from the plasmid and used as a probe in Southern blot. DNA-DNA hybridization with the probe to total DNA from group of bacteria ecologically similar to P. tolaasii including WLORs, fluorescent Pseudomonads isolated from oyster mushroom, P. agarici, P. gingeri, and some of other species of Psedomonas showed that some of the tested bacteria do not have any hybridized band and others have bands sowing RFLP. The cloned DNA fragment or its nucleotide sequence will be useful in detection and identification of the P. tolaasii.

• Journal of Mushroom
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• v.1 no.1
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• pp.28-33
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• 2003

Pseudomonas tolaasii causing brown blotch disease was detected by PCR from water samples collected from the oyster mushroom cultivation farms to find the contamination level of the pathogen in water. Sixteen water samples (28.1%) contain less than 1,000 cfu, 31 samples (54.4%) contain 1,001-10,000 cfu, 6 samples (10.5%) contain 10,001-100,000 cfu, and 4 samples (7%) contain of bacteria per milliliter. P. tolaasii-specific DNA band was amplified in 3 samples (5.3%) by nested-PCR and in 20 samples (35.1%) by immunocapture (IC)-nested PCR respectively. These results suggest that IC-nested-PCR was much more sensitive than nested-PCR in detection of P. tolaasii and a quite few waters using for oyster mushroom cultivation were contaminated with P. tolaasii.

• The Korean Journal of Mycology
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• v.27 no.2 s.89
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• pp.119-123
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• 1999

Genetic diversity of Korean isolates of Pseudomonas tolaasii and WLRO (White line reacting organism) was assessed using BOX-, REP-, and ERIC-PCR analysis. P. tolaasii showed nearly identical band patterns among isolates, whereas considerable DNA polymorphism was found among isolates of WLRO. On the basis of dendogram, WLRO is characterized as a complex group with high degree of genetic differentiation. Genetic relatedness based on repetitive DNA regions was low between P. tolaasii and WLRO isolates.

• The Korean Journal of Mycology
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• v.27 no.2 s.89
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• pp.132-137
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• 1999

This study was carried out to develop the molecular marker for the detection of Pseudomonas tolaasii, a causative agent of bacterial brown blotch disease of oyster mushroom (Pleurotus ostreatus). When several primers designed from repetitive sequences and pectin lyase genes of bacteria were used to produce DNA polymorphism from different Pseudomonas spp. isolated from edible mushrooms, PEU1 primer derived from pectin lyase gene produced polymorphic bands differentiating P. tolaasii strains from other Pseudomonas species. Two bands, 1.0kb and 0.4kb, found commonly in 6 isolates of P. tolaasii were cloned into pGEM-T vector which were designated as pPTOP1 and pPTOP2, respectively, to use as probe. The 0.4 kb insert of pPTOP2 hybridized to only 6 isolates of P. tolaasii, but did not to the other Pseudomonas species. As few as $1.5{\times}10^3$ colony forming unit (cfu) of P. tolaasii could be detected by dot blot hybridization with the cloned 0.4kb DNA in pPTOP2.

• Journal of Food Hygiene and Safety
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• v.16 no.3
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• pp.232-240
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• 2001

One hundred twenty five bacterial isolates were obtained from the brown blotch-diseased oyster mushrooms collected from markets. Among them, 45 were determined as pathogenic bacteria and white line forming organisms(WLFO) were 6 strains and white line reaction organisms (WLRO) were 6 strains. All of the white line forming isolates were identified as Pseudomonas tolaasii which is a known pathogen of brown blotch disease of oyster mushroom by GC-MIS(Gas chromatography-microbial identification system). Six of the white line reacting organisms were identified as P. chlomraphis, P. fluorescens biotype A and type C. The rest of them were P gingeri, P. agarici, P. fluorescens biotype B, P. chloroyaphis, non-pathogenic P. tolaasii, P. putida biotype A and B etc. For spectrum of activity of tolaasin, culture filtrates from pathogenic isolates were examined by browning of mushroom tissue and pitting of mushroom caps. The weak pathogenic bacteria didn't induce browning or pitting of mushroom tissue. On the other hand, strong pathogenic isolates showed browning and pitting reaction on mushroom. An extracellular toxin produced by P. tolaasii, was investigated. The hemolysis activity test of 6 strains identified as P. tolaasii were 0.8∼0.9 at 600 nm and 3 strains of WLRO were 0.9∼1.0 and Pseudomonas app. were 1.0∼1.2. Observation of fresh mushroom tissue using confocal laser scanning microscopy was carried out for images of optical sectioning and vertical sectioning. Also images of brown blotch diseased oyster mushroom tissue after contamination P. tolaasii was obtained by CLSM.

• Korean Journal Plant Pathology
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• v.10 no.3
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• pp.197-210
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• 1994

This experiment was carried out to study the cause of degeneration and rot of cultivated mushroom. Among 597 bacterial isolates derived from the rots of Button mushroom (Agaricus bisporus), Oyster mushroom (Pleurotus ostreatus) and Oak mushroom (Lentinus edodes) collected from markets of 5 cities (Seoul, Suwon, Taegu, Pohang and Pusan) in Korea (1991~1993), 111 bacterial isolates (18.5%) were proved as pathogenic bacteria. These pathogenic bacteria causing bacterial rots of cultivated mushrooms were identified as Pseudomonas tolasii, P. agarici, and Eriwinia sp., and the main causal bacteria were P. tolaasii. P. fluorescens and Klebsiella plenticola were confirmed as saprophytic non-pathogenic bacteria. One hundred fifty nine isolates (Group No. 39) of the 486 saprophytic bacterial isolates were classified as P. fluorescens, and this species was most often found rot area of cultivated mushrooms. P. tolaasii, the causal organism of bacterial blotch, was classified into two groups; One group can be differentiated from the other by the formation of white precipitation band by white line reacting organisms of Pseudomonas Agar F media. P. tolaasii attacked the cultivated mushrooms relatively well at lower incubation temperature such as 5$^{\circ}C$, but P. agarici rarely attack at below 1$0^{\circ}C$. The temperature for the infection commercial cultivated mushrooms by P. agarici was higher than that of P. tolaasii. Optimum temperature for the infection of mushrooms by P. tolaasii and P. agarici were 2$0^{\circ}C$ and $25^{\circ}C$, respectively.

• Korean Journal Plant Pathology
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• v.11 no.4
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• pp.353-360
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• 1995

Tests were performed on 232 bacterial strains (71 strains of Pseudomonas tolaasii and 161 white line reacting organisms, WLRO) isolated from cultivated mushrooms. As results, P. tolaasii was divided into 5 groups on the basis of the phenotypical characteristics for the strains, and group 3 was the major one including 48 (62%) out of the total 71 strains. WLRO were classified into 23 groups, and group 10 was the major group (65 strains, 30% of the total WLRO tested). A white line was well formed at 22$^{\circ}C$ and at 4 mm distance between P. tolaasii and WLRO colonies in their dual culture on Pseudomonas agar F medium within 36-hr incubation, but not formed at $25^{\circ}C$ even for 72-hr incubation. The morphological, cultural and biological properties of P. tolaasii group 3, and the main group of WLRO, group 10, were different only in the light of pathogenicity. Also group 2 of P. tolaasii had the characteristics similar to group 24 of WLRO which was pathogenic to cultivated mushrooms, suggesting the P. tollaasiii and WLRO strains may be the same species although their white line forming ability and pathogenicity were more or less different from one another. Subculture of the strains in P. tolaasii group 1 induced the variation of their pathogenicity, white line forming ability and utilization of sodium benzoate and sodium tartrate, and thus it can be inferred that they were converted to strains having the characteristics of group 3 or WLRO groups.

• The Korean Journal of Mycology
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• v.26 no.1 s.84
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• pp.60-68
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• 1998

The effect of P. agarici and P. tolaasii causing the bacterial disease of mushrooms on the mycelial growth and fruitbody formation of F. velutipes was evaluated in laboratory. When the pathogenic bacteria was inoculated simultaneously with F. velutipes or 5 days after inoculation of F. velutipes, they significantly deterred both mycelial growth and fruitbody formation of F. velutipes in sawdust culture and showed strong inhibition under high population density. They appeared to be tender or milky in exhibiting symptom on F. velutipes by inoculating the concentration of $10^2{\sim}10^6$ of unit/g media, and their growth seemed to be stopped under $10^8\;cfu/g$ media. On $10^2\;cfu/g$ media of P. agarici and $10^4\;cfu/g$ media of P. tolaasii, there was no effect on the fruitbody yield of F. velutipes. P. tolaasii was more suppressive in the mycelial growth of F. velutipes than P. agarici, while on fruitbodies formation of F. velutipes, P. agarici showed slightly higher inhibition than that of P. tolaasii. When the bacteria was inoculated 10 days after inoculation of F. velutipes, both mycelial growth and fruit body formation were not affected nearly.