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In vitro Inhibition of Fungal Root-Rot Pathogens of Panax notoginseng by Rhizobacteria
Guo, Rongjun,Liu, Xingzhong,Li, Shidong,Miao, Zuoqing The Korean Society of Plant Pathology 2009 Plant Pathology Journal Vol.25 No.1
The rhizobacteria of Panax notoginseng were isolated from six sites in Yanshan, Maguan and Wenshan Counties, Yunnan Province of China, and their antagonistic activity against P. notoginseng root-rot fungal pathogens was determined. Of the 574 rhizobacteria isolated, 5.8% isolates were antagonistic in vitro to at least one of the five pathogens, Cylindrocarpon didynum, Fusarium solani, Phytophthora cactorum, Phoma herbarum, and Rhizoctonia solani. The number of rhizo bacteria and the number that inhibited fungi differed depending on sampling sites and isolation methods. Rhizobacteria isolated from the site in Yanshan and Maguan showed more antagonistic effect than them in Wenshan. Heat treatment of rhizosphere soil at $80^{\circ}C$ for 20 min scaled the antagonists up to 14.0%. Antagonistic bacteria in the roots proportioned 3.9% of the total isolates. The most antagonistic isolates 79-9 and 81-4 are Bacillus subtilis based on their 168 rDNA sequence and biochemical and physiological characteristics. Identification and evaluation of antagonistic bacteria against P. notoginseng root-rot pathogens in the main planting areas improved our understanding of their distribution in rhizosphere soil. Furthermore these results indicated that the interactions between biocontrol agent and soil microbes should be seriously considered for the successful survival and biocontrol efficacy of the agents in soil.
In vitro Inhibition of Fungal Root-Rot Pathogens of Panax notoginseng by Rhizobacteria
Rongjun Guo,Xingzhong Liu,Shidong Li,Zuoqing Miao 한국식물병리학회 2009 Plant Pathology Journal Vol.25 No.1
The rhizobacteria of Panax notoginseng were isolated from six sites in Yanshan, Maguan and Wenshan Counties, Yunnan Province of China, and their antagonistic activity against P. notoginseng root-rot fungal pathogens was determined. Of the 574 rhizobacteria isolated, 5.8% isolates were antagonistic in vitro to at least one of the five pathogens, Cylindrocarpon didynum, Fusarium solani, Phytophthora cactorum, Phoma herbarum, and Rhizoctonia solani. The number of rhizo bacteria and the number that inhibited fungi differed depending on sampling sites and isolation methods. Rhizobacteria isolated from the site in Yanshan and Maguan showed more antagonistic effect than them in Wenshan. Heat treatment of rhizosphere soil at 80oC for 20 min scaled the antagonists up to 14.0%. Antagonistic bacteria in the roots proportioned 3.9% of the total isolates. The most antagonistic isolates 79-9 and 81-4 are Bacillus subtilis based on their 16S rDNA sequence and biochemical and physiological characteristics. Identification and evaluation of antagonistic bacteria against P. notoginseng root-rot pathogens in the main planting areas improved our understanding of their distribution in rhizosphere soil. Furthermore these results indicated that the interactions between biocontrol agent and soil microbes should be seriously considered for the successful survival and biocontrol efficacy of the agents in soil.
Hui-Juan Teng,Yue Guo,Jian-Qi Wang,Rongjun Li,Ying-Tang Lu,Lei Zhang 한국식물학회 2016 Journal of Plant Biology Vol.59 No.6
CRK5 is a member of the Arabidopsis thaliana Ca2+-dependent protein kinase-related kinase family. Here, a yeast two-hybrid screen was performed with a truncated form of AtCRK5 as bait to identify interacting proteins and determine its physiological roles. One gene encoding the DWD protein WDRP was isolated. Furthermore, in vitro and in vivo co-immunoprecipitation results strongly supported that these two proteins interact with each other. Using a cell-free degradation assay, we also established that CRK5 was an unstable protein that was degraded through the proteasome pathway. The rate of CRK5 degradation was delayed in a WDRP knockout line. On the other hand, the degradation of CRK5 mediated by WDRP might not affect the phosphorylation of PIN2 by CRK5. Overall, we demonstrated that AtCRK5 interacted with a DWD protein, AtWDRP; the protein AtWDRP targets the kinase for ubiquitin-dependent degradation. Therefore, this report describes a new kinase regulation pathway for CRK family proteins in Arabidopsis.