人参生炭疽菌(Colletotrichum panacicola)和线列炭疽菌(C. lineola)的生物学特性及其对不同杀菌剂的敏感性研究

 近年来,炭疽属真菌(Colletotrichum spp.)引起的人参炭疽病,给人参生产造成了重大经济损失。本文选取分离自我国吉林省栽培人参上的两种炭疽菌人参生炭疽菌(Colletotrichum panacicola)和线列炭疽菌(C. lineola),通过平板培养,测定了它们在不同培养基、温度、碳源、氮源、pH值和光照条件下的生物学特性;采用菌丝生长速率法测定了其对14种杀菌剂的敏感性。结果表明,两种炭疽菌的最适生长温度均为25 ℃,最适生长pH值均为7,光暗交替有利于两种菌的菌丝生长。其中,人参生炭疽菌的菌丝生长最适培养基为V8汁培养基,最适碳源和氮源分别是淀粉和硝酸钾;线列炭疽菌的菌丝生长最适培养基为PDA和PSA培养基,最适碳源和氮源分别是淀粉和硝酸铵;两种炭疽菌对13种药剂敏感,咯菌睛、戊唑醇、抑霉唑、多菌灵、氟环唑、苯醚甲环唑、己唑醇、甲基硫菌灵8种药剂对两种炭疽菌的室内抑菌活性较好,EC₅₀值均小于5.0 μg·mL^-1。咯菌睛、戊唑醇、抑霉唑、多菌灵、氟环唑、苯醚甲环唑、己唑醇、甲基硫菌灵8种药剂对两种炭疽菌的室内抑菌活性较好,EC₅₀值均小于5.0 μg·mL^-1,其中咯菌睛抑菌活性最强,EC₅₀值均小于0.1 μg·mL^-1。两种炭疽菌对同一药剂的敏感性存在差异,线列炭疽菌对吡唑醚菌酯敏感性较高,EC₅₀值小于0.1 μg·mL^-1,而人参生炭疽菌对该药剂的敏感性相对较低(EC₅₀值高于200 μg·mL^-1)。该结果为人参炭疽病发病规律的研究及其田间有效防治奠定了基础。     

防治蔬菜灰霉病枯草芽胞杆菌BAB-1水分散片剂的研制

枯草芽胞杆菌BAB-1是一株有效防治蔬菜灰霉病和白粉病的生防细菌。为提高该菌株的应用潜力,本研究以BAB-1菌株为有效成分开展水分散片剂的研制。通过生物相容性试验、正交试验和单因素试验对崩解剂、粘结剂及分散剂进行筛选,最终确定100亿CFU/g枯草芽胞杆菌BAB-1水分散片剂的适宜配方为酒石酸5%、碳酸氢钠25%、氯化钠0.5%、乳糖5%、PEG6000 2%、NNO 4%,BAB-1母药补足至100%。质量检测结果表明,该水分散片剂崩解时间为272.17 s,pH值为5.75,悬浮率为73.77%,产品各项指标均符合要求。温室盆栽试验结果表明,该制剂500倍液处理能够有效防治黄瓜与番茄灰霉病,防效分别达到84.11%和75.15%,与对照药剂43%氟菌·肟菌酯（露娜森）1000倍液的防治效果无显著性差异（76.25%与84.85%）,但显著高于2亿孢子/g木霉菌可湿性粉剂500倍液（62.71%与57.95%）。     

6种药剂对枸杞炭疽病的防治效果及其残留量的比较

为了筛选针对枸杞炭疽病的高效低残留农药,选用戊唑醇等6种药剂,就其药效及农药残留情况进行了田间比较试验。结果表明:施药后第7天,43%戊唑醇(SC)2 000倍液、40%氟硅唑(EC)6 000倍液、50%异菌脲(WP)1 000倍液、25%嘧菌酯(SC)1 000倍液、25%苯醚甲环唑(EC)1 000倍液和50%多菌灵(WP)500倍液对枸杞炭疽病的防治效果分别为97.00%、76.67%、69.33%、59.00%、56.00%和28.67%,施药后第10天的防治效果分别为92.50%、65.55%、47.41%、45.59%、45.44%和6.44%;戊唑醇的防治效果最好,氟硅唑次之。枸杞干果中戊唑醇的残留含量为2.60 mg·kg-1,低于最大残留限量;氟硅唑的残留含量为0.16 mg·kg~(-1),高于最大残留限量。6种试验药剂中只有戊唑醇符合高效低残留农药的筛选标准,可用于采果期枸杞炭疽病的防治。     

三种杀真菌剂对金龟子绿僵菌产孢及生长的影响

三种杀真菌剂在一定浓度范围为（氯硝胺在１００×１０￣（－６），孟加拉红在５００×１０￣（－６）和柯赛得在２０００×１０￣（－６）内）对金龟子绿僵菌的菌落形成没有明显影响，而柯赛得（含５０％氢氧化铜）和孟加拉红分别在１００×１０￣（－６）和５００×１０￣（－６）浓度时显著地增加金龟子绿僵菌的产孢量，柯赛得还具有缩短产孢时间的作用。氯硝胺在１～１００×１０￣（－６）浓度范围内，随着浓度增加，对产孢能力和菌落大小的抑制作用加强。柯赛得和孟加拉红随浓度的增加对菌落的抑制作用也有所加强，但没有像氯硝胺的抑制作用那么强。     

Fungicidal activity of beta-thujaplicin analogues

The fungicidal activity of analogues of beta-thujaplicin, a natural product responsible for the durability of heartwood of several cupressaceous trees, was investigated in vitro on the growth of different white and brown rot fungi involved in wood biodegradation, Coriolus versicolor, Phanerochaete chrysosporium, Poria placenta and Gloephyllum trabeum. The study shows that 2-hydroxycyclohepta-2,4,6-trienone (tropolone), easily prepared according to a literature procedure, possesses interesting fungicidal activity when compared to beta-thujaplicin, azaconazole, tebuconazole and copper oxine, which suggests this compound should be examined further as a potential biocide for wood preservation.     

Effects of Azoxystrobin on Mycotoxin Production in a Carbendazim-Resistant Strain ofFusarium sporotrichioides

Carbendazim-resistant (RS) and control (CS) strains ofFusarium sporotrichioides Sherb., previously developed in our laboratory, were exposed to graded concentrations of azoxystrob in in broth media under shake-culture conditions for 2, 3, 4 and 8 days. Azoxystrobin concentrations were 0, 1, 10 and 100 mg 1^-1 broth and cultures were incubated at a constant 25°C. Mycelial growth was significantly affected by strain (P<0.01), azoxystrobin concentration (P<0.001) and incubation time (P<0.001). Combined results for the four incubation times showed that CS yielded higher mycelial mass than RS (P<0.01) only in the absence of azoxystrobin. At fungicide additions of 1, 10 and 100 mg P^-1 mycelial growth was reduced (P<0.001) with minimal strain differences (P>0.05) at all three doses of azoxystrobin. Significant (P<0.05 or better) strain-fungicide interactions were recorded in trichothecene production following exposure to azoxystrobin. At 4 and 8 days of incubation, the 10 mg 1^-1 addition of azoxystrobin stimulated T-2 toxin synthesis (P<0.05) only in RS cultures. In contrast, T-2 toxin enhancement in CS cultures occurred only on day 8 but at a lower level of azoxystrobin (1 mg1^-1). Thus, the stimulation of T-2 toxin synthesis depended upon strain and azoxystrobin level. Production of diocetoxyscirpenol (DAS) was affected by a more complex set of interactions. Overall means showed that, in comparison with initial values (on day 2 or 3), DAS output maximized significantly(P<0.05) on day 4 in RS cultures and on day 8 in CS. Marked strain effects were observed on exposure to the 10 mg 1^-1 level of azoxystrobin. At this level, DAS production was enhanced in RS only after 4 (P<0.01 ) and 8 (P<0.05) days of incubation, while in contrast, CS reduced DAS production. As with T-2 toxin, DAS production in CS was stimulated (P<0.05 or better) only at low exposure levels of azoxystrobin. In the case of neosolaniol (NEO), however, the main effect of strain was significant (P<0.05), with CS producing consistently more of the mycotoxin than RS on day 4 of the experiment. At this point, the NEO:T-2 toxin ratio was also higher in CS (0.63) than in RS (0.12), a feature reported by us previously. In conclusion, the present investigation has shown for the first time that the development of resistance to one fungicide can affect trichothecene production inF. sporotrichioides on exposure to a second fungicide. These results have been incorporated into a new classification scheme for fungicide efficacy which is also presented in this paper. http://www.phytoparasitica.org posting Oct. 7,2001.     

Microscopic analysis of the effect of azoxystrobin treatments on Mycosphaerella graminicola infection using green fluorescent protein (GFP)‐expressing transformants

Green fluorescent protein (GFP)‐expressing transformants were used to investigate the effects of strobilurin fungicide azoxystrobin on Mycosphaerella graminicola infection. Azoxystrobin treatments (125 or 250 g AI ha^?1) were applied at various stages of the infection process under controlled conditions. GFP transformants showed conserved in vitro sensitivity to azoxystrobin and pathogenicity. Azoxystrobin controlled over 90% of M graminicola infections when applied before or during penetration of the pathogen (15% of the incubation phase). Azoxystrobin also impaired the growth of intercellular hyphae in M graminicola post‐penetration infection stages when applied at up to 50% of the incubation phase. Incubating infections observed in treated leaves were viable, but their growth was impaired and they did not induce necrosis under controlled conditions. Reduction by half of azoxystrobin dosage had little or no effect on azoxystrobin efficiency in controlling M graminicola. The contribution of post‐penetration fungistatic effect to azoxystrobin curative properties toward M graminicola in a field situation is discussed. © 2001 Society of Chemical Industry     

大麦云纹斑病菌对杀菌剂的抗性检测及同工酶谱类型

1993～1994年大麦云纹斑病菌(Rhynchosporium secalis)对杀菌剂多菌灵、三唑醇的抗药性监测表明,该菌对两种杀菌剂的敏感程度发生了变化,并且首次在田间发现了大麦云纹斑病菌的多抗菌株。这类菌株对多菌灵、乙霉威及三唑醇都具有抗药性,且抗性程度很高。与1990～1991年得到的资料相比,随着杀菌剂选择压力的增加,大田群体中三唑醇高抗菌株比例逐年增加。对该菌同工酶分析结果表明,α—酯酶有7种表现型,磷酸葡萄糖变位酶有2种表现型,过氧化氢酶有3种表现型,无论对去甲基抑制剂类(DMI)表现抗性或敏感菌株,无论调节酶还是非调节酶,其酶谱表现型的变异基本相似。这表明大麦云纹斑病菌对DMI类抗药性突变存在于多个菌系的基因型背景群体中,而不是只起源于单一的广泛分布的菌系。     

The effect of timing of fungicide applications on control of frogeye leaf spot and grain yield of soybeans

Soybean cultivar Samsoy 1, and the breeding lines TGx 849-313D and TGx 996-26E, grown in a field with a heavy epidemic of frogeye leaf spot caused byCercospora sojina, were treated with double foliar applications of the fungicide benomyl. The treatments were made using four application schedules at six different growth stages, starting from V₃ (fully developed leaves, beginning with trifoliate nodes) to R₅ (beginning seed_, to determine the effect of the fungucide timing on frogeye leaf spot severity, soybean grain yield and grain quality. Generally, applications at R₁ (beginning bloom) and R₃ (beginning pod) significantly (P<-0.05) reduced disease severity in the 2 susceptible genotypes, Samsoy 1 and TGx 849-313D. Plot yields of these genotypes were also significantly greater than the untreated controls when the fungicide applications were made at R₁ and R₃. There was no significant difference in diseave severity or grain yield, between the untreated control and the different times of application, on the resistant genotype TGx 996-26E. Improved seed germination and lower levels of seed infection byC. sojina occurred for all fungicide timings in the susceptible genotypes. The results suggest that fungicide spraying initiated at R₁ and followed up at R₃ is most effective in frogeye leaf spot control and can also result in higher grain yields, than applications made earlier or later in the season. Control of frogeye leaf spot, however, is best achieved by growing resistant cultivars.