After retrieving all papers with the theme of "apple ring rot" from 1994 to 2010, the article made a statistical analysis on locations, occurrence degree, regularity, prevention and treatments of apple ring rot acco...After retrieving all papers with the theme of "apple ring rot" from 1994 to 2010, the article made a statistical analysis on locations, occurrence degree, regularity, prevention and treatments of apple ring rot according to published time. The results showed that the occurrence degree of apple ring rot increased year by year, and were uneven among the major apple producing areas with a trend of spreading gradually from east to west. Researchers had paid more attention to control and pharmaceutical experiments of ring rot, while the studies on basic research, projections and forecasts of the disease were not enough. Some prevention and control recommendations of apple ring rot were proposed based on the detailed analysis.展开更多
Apple ring rot,which is caused by Botryosphaeria dothidea,severely affects apple production.The mechanisms employed in apple cells against B.dothidea remain unknown.In this research,the pathogen infection mode and the...Apple ring rot,which is caused by Botryosphaeria dothidea,severely affects apple production.The mechanisms employed in apple cells against B.dothidea remain unknown.In this research,the pathogen infection mode and the relationship between cell death and disease resistance in‘Fuji’/B.dothidea interaction pathosystem were investigated.By using transmission electron microscopy(TEM),our research showed that the pathogen infects apple cells both intracellularly and extracellularly.However,compared with that in immature fruit,the incidence of hyphae in the interior of mature apple fruit cells increased dramatically,suggesting that cell wall-mediated penetration resistance could be important in apple resistance against B.dothidea.TEM ultrastructural characterization identified the nuclear morphology of programmed cell death induction in both apple fruit and callus cells under B.dothidea infection.Overexpression of MdVDAC2(MDP0000271281),which encodes an outer-membrane localized anion channel protein in mitochondria,significantly promoted cell death under B.dothidea infection and simultaneously inhibited pathogen infection,suggesting that cell death represents a disease resistance mechanism in apple against B.dothidea infection.Furthermore,BdCatalase(KAF4307763),a cytochromeP450 family protein BdCYP52A4(KAF4300696),and subtilisin-domain containing proteinswere identified fromB.dothidea-secreted proteins,which suggested the potential involvement of active oxygen species and phytoalexins in combating B.dothidea infection and triggering or dampening apple resistance.Collectively,our research suggested that cell wall-mediated penetration resistance,programmed cell death machinery and microbial effector-interrelated signaling were among strategies recruited in apple to combat B.dothidea.The current research laid the foundation for further investigations into resistance mechanisms in apple.展开更多
基金Supported by Special Fund for Agro-scientific Research in the Public Interest"Species and Damage Characteristic of Pests in Apple" (200903004-42)"Research and Demonstration of Fruit Trees Rot Disease Prevention and Control Technology"(201203034)
文摘After retrieving all papers with the theme of "apple ring rot" from 1994 to 2010, the article made a statistical analysis on locations, occurrence degree, regularity, prevention and treatments of apple ring rot according to published time. The results showed that the occurrence degree of apple ring rot increased year by year, and were uneven among the major apple producing areas with a trend of spreading gradually from east to west. Researchers had paid more attention to control and pharmaceutical experiments of ring rot, while the studies on basic research, projections and forecasts of the disease were not enough. Some prevention and control recommendations of apple ring rot were proposed based on the detailed analysis.
基金supported by the National Key Research and Development Program of China(Grant No.2018YFD1000307)the Natural Science Foundation in China(Grant Nos.31672136 and 31272132).
文摘Apple ring rot,which is caused by Botryosphaeria dothidea,severely affects apple production.The mechanisms employed in apple cells against B.dothidea remain unknown.In this research,the pathogen infection mode and the relationship between cell death and disease resistance in‘Fuji’/B.dothidea interaction pathosystem were investigated.By using transmission electron microscopy(TEM),our research showed that the pathogen infects apple cells both intracellularly and extracellularly.However,compared with that in immature fruit,the incidence of hyphae in the interior of mature apple fruit cells increased dramatically,suggesting that cell wall-mediated penetration resistance could be important in apple resistance against B.dothidea.TEM ultrastructural characterization identified the nuclear morphology of programmed cell death induction in both apple fruit and callus cells under B.dothidea infection.Overexpression of MdVDAC2(MDP0000271281),which encodes an outer-membrane localized anion channel protein in mitochondria,significantly promoted cell death under B.dothidea infection and simultaneously inhibited pathogen infection,suggesting that cell death represents a disease resistance mechanism in apple against B.dothidea infection.Furthermore,BdCatalase(KAF4307763),a cytochromeP450 family protein BdCYP52A4(KAF4300696),and subtilisin-domain containing proteinswere identified fromB.dothidea-secreted proteins,which suggested the potential involvement of active oxygen species and phytoalexins in combating B.dothidea infection and triggering or dampening apple resistance.Collectively,our research suggested that cell wall-mediated penetration resistance,programmed cell death machinery and microbial effector-interrelated signaling were among strategies recruited in apple to combat B.dothidea.The current research laid the foundation for further investigations into resistance mechanisms in apple.