In this research, soil samples were frst polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degrada...In this research, soil samples were frst polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degradation fungus, Fusarium oxysporum (PO-Yi), to investigate the biodegradation of PAEs in pepper and eggplant soil. The findings revealed that PO-Yi can accelerate the degradation of PAEs in vegetable soils including pepper and eggplant soil to varying degrees. The highest absolute degradation rate (up to 39.5%) was observed in DEP-treated soils at the high pollution level (20 mg/kg), which was 14.2% higher than that at the middle pollution level (10 mg/kg). The degradation effect in the pepper soil was superior to that in the eggplant soil. Vegetable soil, either pepper soil or eggplant soil, which was polluted by various PAEs at different pollution gradients and then treated with PO-Yi fungus presented good bioremediation results. In the pepper and eggplant soil, 76.8% and 63.1% of the PAEs with a total volume of 60 mg/kg were degraded within 30 d respectively. PO-Yi, indigenous microorganisms, and the vegetables, i.e. pepper and eggplant had good synergistic effects on the degradation of compound PAEs in PAE-polluted pot soil.展开更多
Konjac (Amorphophallus muelleri), a genus of tuberous plants in the Araceae family, is one of high-value crops in Southwest China. This study aimed at identifying the main pathogens causing tuber rot during storage ...Konjac (Amorphophallus muelleri), a genus of tuberous plants in the Araceae family, is one of high-value crops in Southwest China. This study aimed at identifying the main pathogens causing tuber rot during storage ofA. muelleri and screening the effective fungicides, so as to prolong the storage period ofA. muelleri and decrease the losses. Isolation and identification, as well as pathogenicity test and retro-inoculation experiments were made for the pathogen causing tuber rot during storage ofA. muelleri in Kunming city, Yunnan province, China. The effective fungicides for the main pathogens were also screened in the laboratory. Six fungi were identified as the pathogens causing tuber rot of A. muelleri, which were Fusarium solani (Mart,) Sacc., Fusarium oxysporum Schlecht., Botrytis cinerea Pers., Alternaria alternata (Fr.) Keissl., Rhizopus nigricans Ehrenb., Penicillium ulaiense Hsieh, Su & Tzean. The main pathogens causing postharvest diseases ofA. muelleri were F. solani, F. oxysporum and B. cinerea. The isolation frequencies of them were 33.9%, 10.5% and 19.4%, respectively. After artificial inoculation, the incidence of tubers infected by F. solani, F. oxysporum and B. cinerea was 100%, 83% and 95%, respectively. The results of chemical screening showed that, in potato dextrose agar (PDA) media plate, the compounds Fludioxonil (50% WP) and Boscalid (50% WG) were the most effective in controlling the three main pathogens, and the average effect reached more than 97%. The test of fungicidal antisepsis on tubers consisted ofA. muelleri being dipped in the 9,000x diluted solution of Fludioxonil (50% WP) or in the 3,500x diluted solution of Boscalid (50% WG) for 3 min and stored at room temperature (25 ℃) for 7 d and 15 d, respectively. The fungicidal effects of Fludioxonil against F. solani, F. oxysporum and B. cinerea for 7 d and 15 d were 88.6%/83.2%, 90.1%/84.7% and 93.0%/91.5%, respectively, whereas the fungicidal effects of Boscalid were 87.0%/85.3%, 89.0%/85.6% and 89.2%/89.1%, respectively. The results may provide useful information for the control ofpostharvest diseases ofA. muelleri.展开更多
In this research, soil samples were first polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degradatio...In this research, soil samples were first polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degradation fungus, Fusarium oxysporum (PO-Yi), to investigate the biodegradation of PAEs in pepper and eggplant soil. The findings revealed that PO-Yi can accelerate the degradation of PAEs in vegetable soils including pepper and eggplant soil to varying degrees. The highest absolute degradation rate (up to 39.5%) was observed in DEP-treated soils at the high pollution level (20 mg/kg), which was 14.2% higher than that at the middle pollution level (10 mg/kg). The degradation effect in the pepper soil was superior to that in the eggplant soil. Vegetable soil, either pepper soil or eggplant soil, which was polluted by various PAEs at different pollution gradients and then treated with PO-Yi fungus presented good bioremediation results. In the pepper and eggplant soil, 76.8% and 63.1% of the PAEs with a total volume of 60 mg/kg were degraded within 30 d respectively. PO-Yi, indigenous microorganisms, and the vegetables, i.e. pepper and eggplant had good synergistic effects on the degradation of compound PAEs in PAEpolluted pot soil.展开更多
Fungal diseases often occur seriously in muskmelon in open field of Hubei Province in summer, especially in continuous cropping pattern, resulting in great economic losses. In this study, the pathogens of main fungal ...Fungal diseases often occur seriously in muskmelon in open field of Hubei Province in summer, especially in continuous cropping pattern, resulting in great economic losses. In this study, the pathogens of main fungal diseases in muskmelon in open field of Hubei Province were isolated, and they were identified by morphological and molecular techniques. The results showed that muskmelon fusarium wilt is a major disease in muskmelon in open field of Hubei Province in summer, and its pathogen was confirmed to be Fusarium oxysporum. In future studies, one pair of specific primers would be designed to detect different pathogenic races of Fusarium oxysporum so as to accelerate the detection and to shorten the detection time,thereby proving guidance for actual production.展开更多
Many analytic strategies have emerged to estimate plant responses to Fusarium wilt. The demand for fast and reliable method (diagnosis, prediction) to determine isolate strength accurately is not established yet. Ea...Many analytic strategies have emerged to estimate plant responses to Fusarium wilt. The demand for fast and reliable method (diagnosis, prediction) to determine isolate strength accurately is not established yet. Early determination of pathogen strength helps in plant medication. The aim of this study was to develop a faster strategy and method for early determination of fungal isolates strength in correlation to plant response. Till now, the scientists have no consensus on the most correlated parameters that could express wilt precisely. In this study, 30 isolates of Fusarium oxysporum isolated from Lupinus termis L. were used to provide an explicit image about the real strength of Fusarium isolates and its impact on the plant. Wilting percentage ranged from 26.67% to 93.33% of the infected plants depending on isolate virulence. Some of cellular, morphological and physical measurements were conducted on 8 out of 30 isolates, including root (length, fresh weight (FW) and dry weight (DW)), nodules (water content (WC), FW, DW), stem (height, WC, FW, DW), total leaves/plant (WC, FW, DW) and the fourth leaf (WC, FW, DW, leaf area, epidermal cell area, epidermal cell number, succulence). Hierarchical clustering was used to determine the variance between the isolates. Detrended correspondence analysis (DCA) and canonical correspondence analysis (CCA) were used to determine the most important growth parameters that could express wilting accurately. The CCA results showed that most of the measured parameters on the fourth leaf, except for leaf epidermal cell number, were highly and positively correlated to wilt. That makes these specific parameters valuable and sensitive for any changes in isolates strength. Accordingly, a mathematical model was created to be helpful in the quick determination of isolate strength and precise medication.展开更多
This study aimed to explore whether reductive soil disinfestation(RSD) is an effective method of controlling continuous cropping obstacle of watermelon. Samples of watermelon continuous cropping soils were treated b...This study aimed to explore whether reductive soil disinfestation(RSD) is an effective method of controlling continuous cropping obstacle of watermelon. Samples of watermelon continuous cropping soils were treated by RSD in laboratory tests and pot experiments in August 2015 and from December 10,2016 to April 10,2017. The soil samples for the laboratory test were divided into 16 groups,and each group comprised three parallel samples of 100 g(dry soil weight). Except for the original and control(CK) samples,the 14 other groups of soil samples were treated with different combinations of 1% or 3% alfalfa powder,1% or 3% ammonia(NH3) water,and 1% or 3% acetic acid. The soil samples were placed inside size-five self-styled plastic bags and incubated in a constant-temperature biochemical incubator at 35°C for 14 days after blending,flooding,and sealing. Seven groups of soil samples were designed for the pot experiments based on the laboratory test results. Each group consisted of 30 parallel samples of 3 kg(dry soil weight). These samples were incubated outdoors for 4 months after mixing with alfalfa powder and/or NH3 and/or acetic acid according to the experimental design,blending,flooding,and sealing. Watermelon seedlings were planted in the air-dried soil samples from May to July in 2017. The results showed that the p H of the soil samples treated by RSD were elevated except for those samples with acetic acid. In addition,the electrical conductivities of the soil samples treated by RSD were effectively adjusted. The presence of soil-borne pathogenic Fusarium oxysporum f.sp. niveum was significantly suppressed(p 0.05) in soil samples treated by RSD,and the incidence and mortality rate of watermelons planted in these samples were remarkably lower than those planted in the CK and flooded CK soil samples. Therefore,continuous cropping obstacle of watermelon can be controlled by RSD.展开更多
基金Supported by Hunan Key Research&Development Project(2016SK2053)Innovation Fund Project of Hunan Agricultural Science(2017JC65,2018ZD04)+1 种基金Project of International Joint Lab on Fruits&Vegetables Processing,Quality and Safety(2017)Project of Hunan Key Lab of Fruits&Vegetables Storage,Processing,Quality and Safety(2018)~~
文摘In this research, soil samples were frst polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degradation fungus, Fusarium oxysporum (PO-Yi), to investigate the biodegradation of PAEs in pepper and eggplant soil. The findings revealed that PO-Yi can accelerate the degradation of PAEs in vegetable soils including pepper and eggplant soil to varying degrees. The highest absolute degradation rate (up to 39.5%) was observed in DEP-treated soils at the high pollution level (20 mg/kg), which was 14.2% higher than that at the middle pollution level (10 mg/kg). The degradation effect in the pepper soil was superior to that in the eggplant soil. Vegetable soil, either pepper soil or eggplant soil, which was polluted by various PAEs at different pollution gradients and then treated with PO-Yi fungus presented good bioremediation results. In the pepper and eggplant soil, 76.8% and 63.1% of the PAEs with a total volume of 60 mg/kg were degraded within 30 d respectively. PO-Yi, indigenous microorganisms, and the vegetables, i.e. pepper and eggplant had good synergistic effects on the degradation of compound PAEs in PAE-polluted pot soil.
基金This research was supported by the Science Foundation No. 2011FZ 178, 2011FZ 180, 2014HD004, 14C26215303260 and National Natural Science Foundation of China (NSFC) No. 31260073, 31340019, 31160412, 41361056.
文摘Konjac (Amorphophallus muelleri), a genus of tuberous plants in the Araceae family, is one of high-value crops in Southwest China. This study aimed at identifying the main pathogens causing tuber rot during storage ofA. muelleri and screening the effective fungicides, so as to prolong the storage period ofA. muelleri and decrease the losses. Isolation and identification, as well as pathogenicity test and retro-inoculation experiments were made for the pathogen causing tuber rot during storage ofA. muelleri in Kunming city, Yunnan province, China. The effective fungicides for the main pathogens were also screened in the laboratory. Six fungi were identified as the pathogens causing tuber rot of A. muelleri, which were Fusarium solani (Mart,) Sacc., Fusarium oxysporum Schlecht., Botrytis cinerea Pers., Alternaria alternata (Fr.) Keissl., Rhizopus nigricans Ehrenb., Penicillium ulaiense Hsieh, Su & Tzean. The main pathogens causing postharvest diseases ofA. muelleri were F. solani, F. oxysporum and B. cinerea. The isolation frequencies of them were 33.9%, 10.5% and 19.4%, respectively. After artificial inoculation, the incidence of tubers infected by F. solani, F. oxysporum and B. cinerea was 100%, 83% and 95%, respectively. The results of chemical screening showed that, in potato dextrose agar (PDA) media plate, the compounds Fludioxonil (50% WP) and Boscalid (50% WG) were the most effective in controlling the three main pathogens, and the average effect reached more than 97%. The test of fungicidal antisepsis on tubers consisted ofA. muelleri being dipped in the 9,000x diluted solution of Fludioxonil (50% WP) or in the 3,500x diluted solution of Boscalid (50% WG) for 3 min and stored at room temperature (25 ℃) for 7 d and 15 d, respectively. The fungicidal effects of Fludioxonil against F. solani, F. oxysporum and B. cinerea for 7 d and 15 d were 88.6%/83.2%, 90.1%/84.7% and 93.0%/91.5%, respectively, whereas the fungicidal effects of Boscalid were 87.0%/85.3%, 89.0%/85.6% and 89.2%/89.1%, respectively. The results may provide useful information for the control ofpostharvest diseases ofA. muelleri.
文摘In this research, soil samples were first polluted with 6 PAEs (i.e. DMP, DEP, DIBP, DBP, DEHP, and BBP) at 3 different concentration gradients (0, 10, and 20 mg/kg) and then treated with a highly-efficient degradation fungus, Fusarium oxysporum (PO-Yi), to investigate the biodegradation of PAEs in pepper and eggplant soil. The findings revealed that PO-Yi can accelerate the degradation of PAEs in vegetable soils including pepper and eggplant soil to varying degrees. The highest absolute degradation rate (up to 39.5%) was observed in DEP-treated soils at the high pollution level (20 mg/kg), which was 14.2% higher than that at the middle pollution level (10 mg/kg). The degradation effect in the pepper soil was superior to that in the eggplant soil. Vegetable soil, either pepper soil or eggplant soil, which was polluted by various PAEs at different pollution gradients and then treated with PO-Yi fungus presented good bioremediation results. In the pepper and eggplant soil, 76.8% and 63.1% of the PAEs with a total volume of 60 mg/kg were degraded within 30 d respectively. PO-Yi, indigenous microorganisms, and the vegetables, i.e. pepper and eggplant had good synergistic effects on the degradation of compound PAEs in PAEpolluted pot soil.
基金Supported by Earmarked Fund for China Agriculture Research System(CARS-26-34)
文摘Fungal diseases often occur seriously in muskmelon in open field of Hubei Province in summer, especially in continuous cropping pattern, resulting in great economic losses. In this study, the pathogens of main fungal diseases in muskmelon in open field of Hubei Province were isolated, and they were identified by morphological and molecular techniques. The results showed that muskmelon fusarium wilt is a major disease in muskmelon in open field of Hubei Province in summer, and its pathogen was confirmed to be Fusarium oxysporum. In future studies, one pair of specific primers would be designed to detect different pathogenic races of Fusarium oxysporum so as to accelerate the detection and to shorten the detection time,thereby proving guidance for actual production.
文摘Many analytic strategies have emerged to estimate plant responses to Fusarium wilt. The demand for fast and reliable method (diagnosis, prediction) to determine isolate strength accurately is not established yet. Early determination of pathogen strength helps in plant medication. The aim of this study was to develop a faster strategy and method for early determination of fungal isolates strength in correlation to plant response. Till now, the scientists have no consensus on the most correlated parameters that could express wilt precisely. In this study, 30 isolates of Fusarium oxysporum isolated from Lupinus termis L. were used to provide an explicit image about the real strength of Fusarium isolates and its impact on the plant. Wilting percentage ranged from 26.67% to 93.33% of the infected plants depending on isolate virulence. Some of cellular, morphological and physical measurements were conducted on 8 out of 30 isolates, including root (length, fresh weight (FW) and dry weight (DW)), nodules (water content (WC), FW, DW), stem (height, WC, FW, DW), total leaves/plant (WC, FW, DW) and the fourth leaf (WC, FW, DW, leaf area, epidermal cell area, epidermal cell number, succulence). Hierarchical clustering was used to determine the variance between the isolates. Detrended correspondence analysis (DCA) and canonical correspondence analysis (CCA) were used to determine the most important growth parameters that could express wilting accurately. The CCA results showed that most of the measured parameters on the fourth leaf, except for leaf epidermal cell number, were highly and positively correlated to wilt. That makes these specific parameters valuable and sensitive for any changes in isolates strength. Accordingly, a mathematical model was created to be helpful in the quick determination of isolate strength and precise medication.
基金Quality Engineering Project of Anhui Province(2015zy068)Talents Program of Bengbu University([2014]182)+2 种基金Project of Research Innovation for Jiangsu Province Ordinary University Graduate Student in 2013(CXLX13_370)Project of Professional Engineering Teaching Reform(Environmental Science)(2017GCHZY2)Project of Anhui Revitalization Plan(2014zdjy137)
文摘This study aimed to explore whether reductive soil disinfestation(RSD) is an effective method of controlling continuous cropping obstacle of watermelon. Samples of watermelon continuous cropping soils were treated by RSD in laboratory tests and pot experiments in August 2015 and from December 10,2016 to April 10,2017. The soil samples for the laboratory test were divided into 16 groups,and each group comprised three parallel samples of 100 g(dry soil weight). Except for the original and control(CK) samples,the 14 other groups of soil samples were treated with different combinations of 1% or 3% alfalfa powder,1% or 3% ammonia(NH3) water,and 1% or 3% acetic acid. The soil samples were placed inside size-five self-styled plastic bags and incubated in a constant-temperature biochemical incubator at 35°C for 14 days after blending,flooding,and sealing. Seven groups of soil samples were designed for the pot experiments based on the laboratory test results. Each group consisted of 30 parallel samples of 3 kg(dry soil weight). These samples were incubated outdoors for 4 months after mixing with alfalfa powder and/or NH3 and/or acetic acid according to the experimental design,blending,flooding,and sealing. Watermelon seedlings were planted in the air-dried soil samples from May to July in 2017. The results showed that the p H of the soil samples treated by RSD were elevated except for those samples with acetic acid. In addition,the electrical conductivities of the soil samples treated by RSD were effectively adjusted. The presence of soil-borne pathogenic Fusarium oxysporum f.sp. niveum was significantly suppressed(p 0.05) in soil samples treated by RSD,and the incidence and mortality rate of watermelons planted in these samples were remarkably lower than those planted in the CK and flooded CK soil samples. Therefore,continuous cropping obstacle of watermelon can be controlled by RSD.
