几种杀菌剂对黄瓜疫霉菌的毒力测定

采用菌丝生长速率法检测60%嘧菌酯悬浮剂、80%代森锰锌可湿性粉剂、75%百菌清可湿性粉剂、60%唑醚·代森联水分散粒剂、2%蛇床子素微乳剂、64%杀毒矾可湿性粉剂等6种杀菌剂对黄瓜疫霉菌的室内毒力。结果表明,唑醚·代森联和蛇床子素对黄瓜疫霉菌的毒力最高,EC50值分别为3.4143 mg·L-1和10.4641 mg·L-1。将两种原药混配后,表现出增效作用,在两者混配比为1∶2时增效最明显,EC50值为5.8178 mg·L-1。     

几种常用杀菌剂对胡瓜钝绥螨的影响

采用3种不同的方法测定了5种常用杀菌剂对天敌胡瓜钝绥螨Neoseiulus cucumeris（Oudemans）的影响。结果表明5种杀菌剂中,86．2％铜大师可湿性粉剂8001200倍对胡瓜钝绥螨有较低的影响,喷雾法测定最高浓度800倍校正死亡率为15．00％,而让胡瓜钝绥螨取食经86．2％铜大师可湿性粉剂各浓度药液处理过的山楂叶螨Amphitetranychus viennensis（Zacher）均无二次中毒现象,80％代森锌可湿性粉剂、80％大生M-45可湿性粉剂、50％代森锰锌可湿性粉剂和50％普雅图可湿性粉剂在3种试验方法中各浓度对胡瓜钝绥螨死亡率均与清水对照相当,因此释放捕食螨生防园防治病害可选用对胡瓜钝绥螨影响小的80％代森锌可湿性粉剂800～1000倍、80％大生M-45可湿性粉剂500-600倍、50％代森锰锌可湿性粉剂600-800倍、86．2％铜大师可湿性粉剂12001500倍、50％普雅图可湿性粉剂800-1000倍。     

有效霉素A对棘孢木霉的影响及协同防治玉米纹枯病作用

【背景】玉米纹枯病逐渐发展为制约我国玉米持续增产的主要病害,有效霉素A与生防菌木霉均对纹枯病菌具有抗性,但二者各有优缺点。【目的】研究有效霉素A与木霉菌协同作用的可行性,提高对玉米纹枯病的防治水平,实现抗生素类化学农药的减量使用,提高生态环境安全性。【方法】测定有效霉素A处理后的棘孢木霉GDSF1009的细胞壁降解酶及防御反应相关酶活性,烟草叶片验证活性氧及过敏性反应。利用转录组及气相色谱-飞行时间质谱联用分析有效霉素A对GDSF1009基因表达差异及生长代谢的影响,并进行叶片及平皿协同抑菌实验。【结果】有效霉素A对棘孢木霉GDSF1009的几丁质酶、纤维素酶及木聚糖酶的活性无影响,有效霉素A未进入到棘孢木霉菌细胞内。在转录组水平,有效霉素A处理木霉24h和48 h后,与对照相比,差异基因所占比例分别为8.932%和6.779%,有效霉素A对GDSF1009相关的糖类及脂类代谢没有显著影响,仅对氨基酸代谢相关的基因有一些影响,这些基因并不会造成氨基酸代谢的大量变化。同时验证了在二者联合使用时,可以显著地提高玉米纹枯病的防治效果。【结论】有效霉素A对棘孢木霉菌的初生代谢系统是比较安全的,二者协同作用的抗病效果显著高于单因子作用。     

10种杀菌剂对中华蜜蜂的急性毒性测定及风险评估

明确80%代森锰锌可湿性粉剂、50%啶酰菌胺水分散型粒剂、50%腐霉利可湿性粉剂、50%烯酰吗啉可湿性粉剂、100 g/L氰霜唑悬浮剂、20%叶枯唑可湿性粉剂、2%春雷毒素水剂、12.50%腈菌唑乳油、25%丙环唑乳油和15%咪鲜胺微乳剂等10种杀菌剂对中华蜜蜂Apis cerana cerana工蜂的急性毒性,并评价其对中华蜜蜂工蜂的风险性。在室内采用摄入法和点滴法测定10种杀菌剂对中华蜜蜂工蜂的急性经口和接触毒性。结果表明代森锰锌,啶酰菌胺,腐霉利等7种杀菌剂对中华蜜蜂的急性毒性均为低毒;腈菌唑和丙环唑对中华蜜蜂的急性经口毒性和急性接触毒性均为中毒,咪鲜胺对中华蜜蜂的急性经口毒性为高毒,急性接触毒性为中毒;这3种杀菌剂且均属于中等风险性。建议禁止咪鲜胺在蜜源作物开花授粉期施用,慎重选择中等毒性杀菌剂腈菌唑和丙环唑,尽量选择对蜜蜂低毒的杀菌剂,以保护中华蜜蜂的安全。     

积雪草漆斑病病原鉴定及室内药剂筛选

近年来,在广西各地积雪草种植基地,出现一种为害极重的病害,该病害病原菌主要为害积雪草叶片、叶柄,可致使叶片大面积枯死,该病害发生普遍、侵染期长,严重影响积雪草药材的品质和产量。该研究采用常规组织分离法从积雪草病叶上分离病原菌并根据柯赫氏法则验证其致病性;通过菌落特征、菌株形态及ITS序列分析鉴定病原菌;在室内利用生长速率法测定10种杀菌剂对该菌的抑制活性。结果表明：为害积雪草叶片的病原菌为泛生漆斑菌( Myrothecium inundatum);该菌侵染性强,接种至健康积雪草叶片后24 h即可发病,并迅速扩展引起叶片萎蔫;杀菌剂60％唑醚?代森联水分散粒剂、45％恶霉灵?甲霜可湿性粉剂、1.8％辛菌胺醋酸盐水剂、80％代森锰锌可湿性粉剂室内对积雪草漆斑病病原菌的抑菌率均在98％以上,抑菌效果极强,建议在生产中轮换应用防治积雪草漆斑病。15％咪鲜胺微乳剂、70％甲基硫菌灵可湿性粉剂和10％苯醚菌酯悬浮剂对该病原菌的抑菌率也均在92％以上,抑菌效果良好,在生产中可酌情考虑使用。     

木霉菌对3种致病真菌的作用关系研究

采用室内生长速率法测定了木霉菌 (Trichodermaspp .)与 3种致病真菌的互作关系 ,结果表明 ,木霉菌与 3种致病真菌间均存在明显的互作关系 ,但其互作类型与作用强度各不相同 :木霉菌与立枯丝核菌 (Rhi zoctoniasolani)间存在拮抗作用 ,但抑制强度不大 ;木霉菌与腐霉菌 (Pythiumaphanidermatum)不仅存在拮抗作用 ,且对腐霉菌的抑制强度较大 ;木霉菌与镰刀菌 (Fuariumspp .)间存在明显的协生作用。经进一步多方面考察后 ,有可能将该木霉菌用于病害防治     

木霉菌防治植物真菌病害研究进展

木霉菌是一种重要的植物病害生防因子,尤其在防治植物病原真菌病害中一直受到极大的关注。木霉菌依靠其菌株在包括趋向生长、识别、接触、缠绕与穿透等步骤的真菌寄生过程中分泌产生的几丁质酶、葡聚糖酶、纤维素酶、蛋白酶等一系列细胞壁降解酶,进行重寄生作用,拮抗其他植物病原菌,行使其生防功能。我们简要概述了木霉菌的种类、拮抗对象、抑菌机制、诱导抗性、促生作用、基于分子生物学的转基因工程研究,以及木霉菌在植物病原真菌生物防治中的应用。     

苹果套袋果实黑点病菌杀菌剂室内测定研究

为筛选有效抑制套袋苹果黑点病多种病原的杀菌剂,选择25%吡唑醚菌酯悬浮剂、250 g/L嘧菌酯悬浮剂、10%苯醚甲环唑水分散粒剂、430 g/L戊唑醇悬浮剂、30%氟菌唑可湿性粉剂和80%克菌丹水分散粒剂6种杀菌剂,采用菌丝生长速率法,对引起套袋苹果黑点病的6种主要病原菌进行室内抑菌活性测定,获得了对多种黑点病病原具有抑制活性的杀菌剂。嘧菌酯、吡唑醚菌酯、戊唑醇和苯醚甲环唑4种杀菌剂对6种病原具有较好的抑菌活性,EC₅₀均小于20μg/mL,具较好田间应用前景。结果说明甲氧基丙烯酸酯类杀菌剂嘧菌酯、吡唑醚菌酯和三唑类杀菌剂戊唑醇、苯醚甲环唑有望作为交替使用防治套袋苹果黑点病的候选农药。     

新型微生物杀真菌剂诺沃霉素稳定性研究

诺沃霉素是一种新型微生物杀真菌剂,具有广谱抗真菌活性。该产物目前用于农作物杀菌剂的开发。为评价该化合物的开发前景,进行了诺沃霉素在加热、光照、室温贮存等条件下的稳定性测试。结果表明,诺沃霉素在环境pH 5.0~6.0时较为稳定,对紫外线及阳光有较好的稳定性。诺沃霉素水乳剂稳定性较差,但制成可湿性粉剂后,基本满足农药稳定性要求。     

贵州地区木霉菌分离鉴定及对辣椒疫霉的拮抗作用

【背景】辣椒疫霉是一种毁灭性的土传病害,当前主要使用化学合成杀菌剂防治,但容易导致环境污染和食品安全等问题。【目的】筛选可拮抗辣椒疫霉的候选菌株,探究分离菌株拮抗辣椒疫霉的生理生化作用机制。【方法】综合应用形态学、核糖体RNA (rRNA)基因非转录区ITS序列相似性方法鉴定分离菌株,通过对峙实验筛选抑菌效果较高的拮抗菌株,基于比色法测定分离菌株发酵液粗提物对辣椒疫霉菌丝脂质过氧化、纤维素酶、β-葡萄糖苷酶(β-GC)和多聚半乳糖醛酸酶(PG)活性的影响。【结果】从腐木和土壤样品中分离得到11株木霉,分属于绿色木霉(Trichodermavirens)、哈茨木霉(Trichoderma harzianum)、钩状木霉(Trichoderma hamatum)和棘孢木霉(Trichoderma asperellum) 4个种。11株木霉对辣椒疫霉均有一定的抑制作用,抑制率达到90%以上的菌株包括:绿色木霉Tv-1(92.68%)、Tv-2 (95.12%),哈茨木霉Thz-2 (92.68%),钩状木霉Tha-1 (90.24%)。以4株高效木霉的发酵液粗提物处理辣椒疫霉菌丝5 d后,因脂质过氧化产生的丙二醛含量显著增加,分别达到1.20、1.48、2.69和3.16 nmol/g,显著高于对照处理的0.77 nmol/g;与对照组相比,β-GC、PG酶活性显著下降,分别降低了12.28%-64.91%、7.2%-15.5%;同时纤维素酶活性呈上升趋势,最显著组为2.647 U/mL,相对于对照组增加了0.831U/mL。【结论】分离得到4株明显抑制辣椒疫霉菌生长的高效木霉菌,主要通过破坏细胞壁结构、降低致病因子酶活力和增强脂质过氧化等方式起拮抗作用,可为辣椒疫病的生物防治提供理论依据和技术支持。     

Biocontrol of aerial plant diseases in agriculture and horticulture: current approaches and future prospects

Until recently, the majority of research on the biological control of aerial plant diseases was focused on control of bacterial pathogens. Such research led to the commercialization of the biocontrol agent Pseudomonas fluorescens A506, as BlightBan A506™, for control of fire blight of pear. In contrast, chemical fungicides typically have provided adequate control of most foliar fungal pathogens. However, fungicide resistance problems, concerns regarding pesticide residues and revocation of registration of certain widely used fungicides have led to increased activity in the development of biocontrol agents of foliar fungal pathogens. Much of this activity has centered around the use of Trichoderma spp and Gliocladium spp to control Botrytis cinerea on grape and strawberry. The biocontrol agent Trichoderma harzianum T39 is commercially available in Israel, as Trichodex ™, for control of grey mold in grapes and may soon be registered for use in the US. Also targeted primarily against a foliar disease of grapes, in this case powdery mildew caused by Uncinula necator, is the biocontrol agent Ampelomyces quisqualis AQ10, marketed as AQ^{10  TM} biofungicide. Another promising development in the area of foliar disease control, though one which is not yet commercialized, is the use of rhizobacteria as seed treatments to induce systemic resistance in the host plant, a strategy which can protect the plant against a range of bacterial and fungal pathogens. Received 06 February 1997/ Accepted in revised form 05 June 1997     

Antagonistic potentiality of Trichoderma harzianum towards seed-borne fungal pathogens of winter wheat cv. Protiva in vitro and in vivo

The antagonistic effect of Trichoderma harzianum on a range of seed-borne fungal pathogens of wheat (viz. Fusarium graminearum, Bipolaris sorokiniana, Aspergillus spp., and Penicillium spp.) was assessed. The potential of T. harzianum as a biocontrol agent was tested in vitro and under field conditions. Coculture of the pathogens and Trichoderma under laboratory conditions clearly showed dominance of T. harzianum. Under natural conditions, biocontrol effects were also obtained against the test fungi. One month after sowing, field emergence (plant stand) was increased by 15.93% over that obtained with the control treatment, and seedling infection was reduced significantly. Leaf blight severity was decreased from 22 to 11 at the heading stage, 35 to 31 at the flowering stage, and 86 to 74 at the grain filling stage. At harvest, the number of tillers per plant was increased by 50%, the yield was increased by 31.58%, and the 1,000-seed weight was increased by 21%.     

Interactions of Bacillus spp. and plants--with special reference to induced systemic resistance (ISR)

Biological control of soil-borne pathogens comprises the decrease of inoculum or of the disease producing activity of a pathogen through one or more mechanisms. Interest in biological control of soil-borne plant pathogens has increased considerably in the last few decades, because it may provide control of diseases that cannot or only partly be managed by other control strategies. Recent advances in microbial and molecular techniques have significantly contributed to new insights in underlying mechanisms by which introduced bacteria function. Colonization of plant roots is an essential step for both soil-borne pathogenic and beneficial rhizobacteria. Colonization patterns showed that rhizobacteria act as biocontrol agents or as growth-promoting bacteria form microcolonies or biofilms at preferred sites of root exudation. Such microcolonies are sites for bacteria to communicate with each other (quorum sensing) and to act in a coordinated manner. Elicitation of induced systemic resistance (ISR) by plant-associated bacteria was initially demonstrated using Pseudomonas spp. and other Gram-negative bacteria. Several strains of the species Bacillus amyloliquefaciens, B. subtilis, B. pasteurii, B. cereus, B. pumilus, B. mycoides, and B. sphaericus elicit significant reductions in the incidence or severity of various diseases on a diversity of hosts. Elicitation of ISR by these strains has been demonstrated in greenhouse or field trials on tomato, bell pepper, muskmelon, watermelon, sugar beet, tobacco, Arabidopsis sp., cucumber, loblolly pine, and two tropical crops (long cayenne pepper and green kuang futsoi). Protection resulting from ISR elicited by Bacillus spp. has been reported against leaf-spotting fungal and bacterial pathogens, systemic viruses, a crown-rotting fungal pathogen, root-knot nematodes, and a stem-blight fungal pathogen as well as damping-off, blue mold, and late blight diseases. This progress will lead to a more efficient use of these strains which is worthwhile approach to explore in context of biocontrol strategies.     

Biological control of southern corn leaf blight by Trichoderma atroviride SG3403

Trichoderma atroviride SG3403 showed high biocontrol activity against southern corn leaf blight (SCLB; pathogen: Cochliobolus heterostrophus). T. atroviride SG3403 could cause death of C. heterostrophus race O hypha on plates. Spraying T. atroviride SG3403 conidia suspension over maize seedling leaves protected the corn from SCLB infection. Biocontrol effect lasted for 30 days in the field. Trichoderma strain was able to induce resistance response in corn leaves against pathogen infection. In corn leaves treated with T. atroviride SG3403, the enzyme activities of phenylalanine ammonia lyase (PAL) and superoxide dismutase (SOD) reached the highest at 24 h, enzyme activity of catalase (CAT) reached the highest at 36 h after inoculation of pathogen C. heterostrophus race O. RNA expression levels of Pal, Sod and Cat (which synthesis enzyme PAL, SOD and CAT) were also upregulated and corresponded to the enzyme activity at the same time point. Enzyme activities and corresponding genes expression induced by Trichoderma SG3403 was more obvious than that induced by pathogen only, which implies that T. atroviride SG3403 induced corn defense gene expression against pathogen infection. Thus, induced resistance mechanism was possibly involved in the biocontrol of SCLB by T. atroviride SG3403.     

木霉防治灰霉病的研究进展

植物病害的生物防治是降低化学农药用量、减少环境污染的一种有效方式,木霉是现在普遍应用且生防潜力巨大的灰霉病防治真菌。目前,已经对防治灰霉的木霉菌株的筛选、应用及生防机制进行了大量而深入的研究。木霉的生防机制分为直接生防机制和间接生防机制,前者主要指木霉与灰霉病菌直接作用过程中所涉及的重寄生、抗生和营养竞争,后者是木霉通过诱导植物产生系统抗性来防治灰霉。本文对木霉直接防治灰霉病以及诱导植物产生系统抗性防治灰霉病所涉及的互作模式、信号传导途径以及所引起的防御反应进行综述,旨在通过机制的深入研究能够找到进一步提高木霉生防效果的技术方案。     

Suppression of southern corn leaf blight by a plant growth-promoting rhizobacterium Bacillus cereus C1L

Southern corn leaf blight (SCLB) is an important foliar disease of maize. In this study, an induced systemic resistance (ISR)-eliciting rhizobacterium Bacillus cereus C1L was used to protect maize against SCLB. Application of B. cereus C1L in maize rhizosphere effectively protected maize from SCLB under greenhouse and field conditions. The protection effect of B. cereus C1L was similar to that of Maneb (2 kg active ingredient per hectare), a recommended fungicide. Furthermore, possible factors of B. cereus C1L to elicit ISR and to promote plant growth were investigated. The results indicate that secreted factors and rhizosphere colonisation ability of B. cereus C1L are involved in ISR elicitation. In addition to biocontrol activity, B. cereus C1L was able to promote growth of maize in field. Compared with a non-treated control, leaf length, leaf width, plant height and fresh and dry weights of B. cereus C1L-treated corn plants significantly increased. Therefore, B. cereus C1L acts as a plant growth-promoting rhizobacterium of maize.     

Biological spectrum of Trichoderma harzianum Rifai isolates to control fungal diseases of tomato (Solanum lycopersicon L.)

Three Trichoderma harzianum isolates viz., Th-Sks, Th-Ke and Th-Ar collected from respective states of India viz., Rajasthan, Kerala and Andhra Pradesh were evaluated for the management of six fungal diseases namely damping off, Fusarium wilt, Rhizoctonia wilt, early leaf spot, late blight and Septoria leaf spot in tomato. During in vitro analysis, T. harzianum isolates inhibited the pathogens’ growth. Isolate Th-Sks was the most virulent antagonist against all the test pathogens and exhibited maximum of 79.47% growth inhibition of Phytophthora infestans. Isolate Th-Sks proved most effective at suppression efficacy in the range of 95–100% and 91–100% against all diseases under glasshouse and in the field conditions, respectively. Tomato seeds treatment with isolate Th-Sks also promoted plant height (78.23 cm) and fruits yield (290 g/plant) during field trial and data were found to be not-significantly different from other isolates. Thus, it is concluded that isolate Th-Sks can be utilised as a biocontrol agent for management of fungal diseases in tomato.     

T90-1木霉菌的筛选和对草莓灰霉病菌作用机制的研究

木霉菌（Trichoderma）作为一种重要的生防因子,可以产生几丁质酶降解植物的多种病原真菌细胞壁。利用低能离子束注入木霉菌使其产生变异,再通过初筛选和复筛选两个过程,获得T90_1木霉菌株,并用草莓灰霉病菌（Botrytis cinerea Pers.）来检验T90_1防治真菌病害的能力。发现该菌株通过侵染、缠绕等多种重寄生方式,并分泌降解病原真菌细胞壁的物质,使病原菌原生质外渗,改变细胞内有序的代谢状况,从而抑制或杀死病原菌。初步揭示该菌株抗真菌的相关机制。     

Effect of <Emphasis Type="Italic">Trichoderma</Emphasis> spp. isolates for biological control of tan spot of wheat caused by <Emphasis Type="Italic">Pyrenophora tritici-repentis</Emphasis> under field conditions in Argentina

Trichoderma spp. have been used as biocontrol agents to protect plants against foliar diseases in several crops, but information from field assays is scarce. In the present work, experiments were carried out to determine the effect of six isolates of Trichoderma harzianum and one isolate of T. koningii on the incidence and severity of tan spot, caused by Pyrenophora tritici-repentis (anamorph: Drechslera tritici-repentis) under field conditions. Significant differences between years, wheat cultivars and treatments were found. In 2003, two of the isolates assayed (T5, T7) showed the best performance against the disease applied as seed treatments or sprayed onto wheat leaves at different stages. The application of six of the treatments on wheat plants significantly reduced disease severity by 16 to 35% in comparison with the control. Disease control provided by isolate T7 was similar to that provided by the fungicide treatment (56% reduction). This is the first report on the efficacy of Trichoderma spp. against tan spot under field conditions in Argentina.