撕裂蜡孔菌的新功能——防治茄子绵疫病及促生效应

doi:10.3864/j.issn.0578-1752.2018.12.007

摘要/Abstract

摘要： 【目的】生物农药和生物肥料安全性好，但种类较少，效果欠佳，亟需增加种类，提高药效和肥效。茄子是人们日常食用的大宗蔬菜，防治其病害，改善植物营养，提高产量和品质是亟待解决的生产问题。撕裂蜡孔菌（Ceriporia lacerate）分布广泛，起源复杂，功能多样，已用于医药、环保、生物能源等领域，论文进一步挖掘其农用功能。【方法】以自主分离获得的撕裂蜡孔菌新株HG2011为供试菌株，利用Bonnet液体培养基制备发酵液，谷壳、玉米粉和蛭石等制备固体菌剂，通过纯培养、拮抗、盆栽和田间试验，研究该菌株的胞外酶分泌，对辣椒疫霉（Phytophthora capsici)的拮抗效应、茄子绵疫病的防治效果，以及对茄子植株氮、磷、钾养分吸收和产量品质的影响。【结果】撕裂蜡孔菌HG2011菌株能分泌纤维素酶、β-1,3-葡聚酶、蛋白酶及磷酸酶，在发酵液中的活性分别为 46.11、63.02、199.33和27.25 U·mL^-1。在拮抗试验中，HG2011菌株发酵液显著抑制辣椒疫霉生长，抑制率为36.13%—60.59%；其菌丝还能侵入疫霉菌落，造成疫霉菌丝变形、断裂和消融。接种辣椒疫霉使盆栽茄子植株的发病率超过50%，病情指数为64.50；而在施用HG2011菌株发酵液的处理中，发病率为10.50%—18.52%，病情指数为13.46—20.60，防治效果为68.06%—79.13%，预防效果优于治疗效果。田间施用固体菌剂之后，茄子植株氮、磷、钾累积量和吸收效率最高，单施化肥次之，不施肥最低。与单施化肥相比，植株氮、磷、钾积累量分别增加30.99%—47.72%、19.97%—43.40%和11.21%—41.34%，吸收效率上升31.01%—47.74%、19.80%—43.40%和11.21%—41.34%，肥料偏生产力提高5.88%—18.43%、5.91%—18.44%和5.88%—18.43%，茄子植株生物量和果实产量的增幅分别达30.00%和16.06%。此外，施用固体菌剂显著提高茄子果实氮、维生素C、可溶性蛋白和游离氨基酸含量，比单施化肥依次增加13.86%—20.79%、62.46%—65.30%、36.30%—37.67%和25.46%—33.08%。【结论】撕裂蜡孔菌HG2011菌株抑制辣椒疫霉菌丝生长，使其变形、断裂和消融，降低茄子绵疫病的发病率和病情指数，预防效果优于治疗效果；田间施用撕裂蜡孔菌HG2011固体菌剂促进茄子植株吸收养分，刺激生长，提高产量，改善品质。因此，撕裂蜡孔菌新株HG2011及新作用¾¾防病促生效应的发现扩展了其生物学功能，丰富了生防菌及促生菌的种质资源库，具有潜在的应用前景。

关键词: 撕裂蜡孔菌, 茄子, 辣椒疫霉, 养分

Abstract: 【Objective】 Bio-pesticides and bio-fertilizers are safe and environment friendly, but need to find more effective strains to increase efficiencies in biological control and fertilization practice. Eggplant (Solanum melongena) is an indispensable vegetable in our country. It is an urgent production problem to effectively control diseases, improve plant nutrition, increase yield and quality. Ceriporia lacerate has been used in human disease treatment, environmental protection, bioenergy and other field. The objective of this study is to explore the potential of this fungus further in plant disease control and nutrition improvement. 【Method】 A new self-isolated C. lacerate (strain HG2011) was grown in Bonnet liquid medium and mixture made of rice husk, vermiculite, and maize powder, respectively, to produce culture broth and solid inoculant. By pure culture, antagonism, pot culture and field experiment, a several experiments were performed to detect extracellular enzyme activity in culture broth, antagonism against Phytophthora capsici on culture plate, biological control of phytophthora blight in greenhouse, nutrient uptake, including nitrogen, phosphorus, and potassium, and changes in yield and quality of eggplant in field as affected by this new fungal strain. 【Result】 C. lacerate HG2011 strain could produce cellulase, β-1,3-glucanase, protease and phosphatase, with the activities of 46.11, 63.02, 199.33, and 27.25 U·mL^-1, respectively, in the culture broth. Moreover, the culture broth C. lacerate HG2011 inhibited the hyphal growth of P. capsici, with inhibition rate of 36.13%-60.59% on antagonism plate. In duel culture, this antagonistic fungus could cover P. capsici colonies and make the hyphae deformed, broken and melted. In greenhouse pot experiment, P. capsic was successful to infect eggplants through inoculation, with phytophthora blight incidence over than 50% and disease index of 64.50. After application of C. lacerate HG2011 culture broth, the disease incidence decreased to 10.50%-18.52%, the disease index was 13.46-20.60 and control efficiency was 68.06%-79.13%. The preventive effect was better than that of therapy. Seedlings supplied with the fungal solid inoculant in combination with chemical fertilizers showed the highest nutrient absorption efficiency, followed by only chemical fertilizer and control (without fertilizer). Compared with sole chemical fertilizer, C. lacerate solid inoculant increased nitrogen, phosphorus, and potassium accumulation in eggplant seedlings by 30.99%-47.72%, 19.97%-43.40%, and 11.21%-41.34%, absorption efficiency by 31.01%-47.74%, 19.80%-43.40% and 11.21%-41.34%, fertilizer partial productivity by 5.88%-18.43%, 5.91%-18.44%, and 5.88%-18.43%, plant biomass by more than 30.00%, and fruit yield by over than 16.06%. Nitrogen, vitamin C, soluble protein, and free amino acids in the fruit were enhanced by 13.86%-20.79%, 62.46%-65.30%, 36.30%-37.67%, and 25.46%-33.08%, respectively, under C. lacerate solid inoculant treatments. 【Conclusion】 C. lacerate HG2011 strain inhibited hyphal growth of P. capsici, made it deform, break and melt, and reduced the incidence and disease index of eggplant phytophthora blight. The preventive effect was better than that of therapy. The application of the fungal inoculant promoted the nutrient absorption, stimulated the seedling growth, increased the yield, and improved fruit quality of eggplants in the field. Therefore, the new C. lacerate HG2011 strain and the founding of its new roles in plant disease control and growth promotion extended its biological functions, enriched the members in microbe source bank, and showed a promising potential in plant protection and fertilization.

Key words: Ceriporia lacerate, Solanum melongena, Phytophthora capsici, nutrient

殷洁，范倩，黄建国. 撕裂蜡孔菌的新功能——防治茄子绵疫病及促生效应[J]. 中国农业科学, 2018, 51(12): 2300-2310.

YIN Jie, FAN Qian, HUANG JianGuo. New Functions of Ceriporia lacerate in Phytophthora Blight Control and Growth Promotion of Eggplants[J]. Scientia Agricultura Sinica, 2018, 51(12): 2300-2310.

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