巨大芽胞杆菌YB-3的筛选、鉴定及其对生姜青枯病的生防效果研究

青枯病（bacterial wilt）是生姜上的一种细菌土传毁灭性病害,化学防治易污染环境且常规化学药剂很难在土壤中起到持续控病的作用,生物防治是其理想的防治方法。为开发对生姜青枯病有效的生防措施,对从生姜根际土壤中分离的一株生防细菌YB-3进行了鉴定,并对其生物学特性及生防效果进行了研究,以丰富生防菌株资源库。采用抑菌圈法筛选拮抗细菌,对效果最好的拮抗菌株做盆栽试验,测定其对生姜青枯病的防治效果,根据形态特征、生理生化特性以及16S rDNA序列对筛选得到的优良菌株进行鉴定。试验结果表明,该拮抗菌在平皿上对青枯菌的抑菌率为50.67%,盆栽试验对青枯病的防治效果为60.86%;经16S rDNA序列分析,并结合形态学和生理生化特征,将菌株YB-3鉴定为巨大芽胞杆菌Bacillus megaterium。YB-3是一株具有开发利用价值的姜青枯病生防菌株。     

杀线虫苏云金芽胞杆菌NBIN-863高含量悬浮剂的研制

目前我国微生物农药原药生产技术已达到甚至超过发达国家水平,但制剂技术却存在较大差距,主要体现在剂型结构不合理、制剂质量差、农药助剂种类及品种少、剂型加工工艺总体水平还比较落后等方面。苏云金芽胞杆菌（Bt）等功能微生物产品的市场容量及应用效果与剂型是密切相关的。为了明确新型生物杀线剂NBIN-863的最佳施用剂型,特开展此试验。通过对防腐剂、分散剂、悬浮剂等不同助剂的选择,研制了一种高含量Bt悬浮剂（5.2×10⁹～7.9×10⁹CFU/mL）。配方优化试验表明,在Bt发酵液中加入0.4%防腐剂山梨酸钾、1.0%分散剂硅酸镁铝、4.0%悬浮剂木质素磺酸钙,用盐酸调节pH至4.5,54℃热储前芽胞数最高为7.9×10⁹ CFU/mL,对秀丽隐杆线虫活性最高,LC₅₀为2.83 mg/L,对黄瓜根结线虫田间防效达68.64%。综合各指标,尤其是对秀丽隐杆线虫的半致死浓度,杀线虫NBIN-863悬浮剂（7.9×10⁹ CFU/mL）效果最好,不仅流动性好,而且耐贮藏,是防治作物根结线虫病的理想药剂。     

凝结芽孢杆菌对感染产气荚膜梭菌肉鸡生长性能、肠道病变及免疫器官指数的影响

本试验旨在研究日粮中添加凝结芽孢杆菌对感染产气荚膜梭菌肉鸡生长性能、肠道病变及免疫器官指数的影响。选用312只1日龄科宝500肉鸡公雏,随机分成4个处理,每个处理6个重复,每个重复13只鸡。采用2×2双因子完全随机设计,产气荚膜梭菌分为无感染产气荚膜梭菌组和感染产气荚膜梭菌组,日粮中凝结芽孢杆菌水平分别为0和400mg/kg。试验期35d。结果表明,感染产气荚膜梭菌后15~35日龄肉鸡平均日增重显著降低(P0.05),28日龄肠道病变严重(P0.01),35日龄法氏囊指数极显著降低(P0.01);日粮中添加凝结芽孢杆菌可显著提高15~35日龄肉鸡平均日增重(P0.05),显著降低料重比(P0.05),能缓解感染导致的肠道损伤(P0.05),28日龄肉鸡胸腺指数极显著提高(P0.01),35日龄法氏囊指数极显著提高(P0.01)。肠道病变结果分析表明,日粮中添加凝结芽孢杆菌与感染产气荚膜梭菌有显著交互作用(P0.05)。综上所述,日粮中添加凝结芽孢杆菌能够提高感染产气荚膜梭菌肉鸡生长性能及免疫器官指数,增强动物免疫能力,并能缓解由于产气荚膜梭菌感染而导致的不利影响。     

地衣芽孢杆菌对发酵床饲养仔猪生长性能、消化酶活性及肠道主要菌群数量的影响

本试验旨在研究发酵床饲养模式下日粮中添加地衣芽孢杆菌对仔猪生长性能、胰腺和小肠黏膜消化酶活性及肠道主要菌群数量的影响。选用108头体重13kg左右的35日龄健康苏钟猪,随机分为3组,每组3个重复,每个重复12头,分别饲喂基础日粮(对照组)、基础日粮+40mg/kg杆菌肽锌+20mg/kg硫酸黏杆菌素(抗生素组)、基础日粮+300mg/kg地衣芽孢杆菌(益生菌组)的试验日粮。预试期7d,正试期52d。结果表明:1与对照组相比,日粮中添加地衣芽孢杆菌能够在一定程度上提高仔猪平均日增重、平均日采食量,降低料重比,但各组间差异均不显著(P0.05)。2与对照组相比,日粮中添加地衣芽孢杆菌能够极显著提高仔猪胰腺中淀粉酶活性、十二指肠黏膜中麦芽糖酶活性和空肠黏膜中乳糖酶活性(P0.01),十二指肠黏膜和空肠黏膜中蔗糖酶活性显著提高(P0.05)。3与对照组相比,日粮中添加地衣芽孢杆菌能够显著提高仔猪盲肠芽孢杆菌数量(P0.05);乳酸杆菌数量较对照组提高4.09%,大肠杆菌数量较对照组降低4.86%,但均未达到显著水平(P0.05)。综上所述,在本试验条件下,日粮中添加300mg/kg地衣芽孢杆菌能够提高发酵床饲养仔猪胰腺、小肠黏膜消化酶活性及盲肠芽孢杆菌数量,同时仔猪生长性能也在一定程度上有所改善。     

三株不同形状伴孢晶体的苏芸金杆菌对几种害虫的毒力测定

我们从落叶松毛虫(Dendrolimus sibiricus)、印度谷斑螟(Pyralis farinali)幼虫和森林土壤中分离到产生不同形状伴孢晶体的苏芸金杆菌(Bacillus thuringiensis),对三株菌进行了形态特征的电子显微镜观察、生理生化特性的测定及营养细胞的酯酶型分析,并对几种昆虫进行了室内生物测定,表现出不同的毒力。     

苏云金芽孢杆菌菌种保藏

采用砂土管和滤纸片两种保藏方法，对分属３１个亚种的６１株有代表性的苏云金芽孢杆菌经过１－２３年保存后的菌体存活情况，形态特征及对林业主要害虫舞毒蛾幼虫的杀虫活性进行了试验，并对苏云金芽孢杆菌５个亚种的标准菌株和保存不同年限后的１１项生理生化特性及酯酶型进行了测定。     

Inheritance and cross-resistance of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> insecticidal crystal protein Cry1Ac resistance in cotton bollworm <Emphasis Type="Italic">Helicoverpa armigera</Emphasis> Hubner population from Tamil Nadu,India

Cotton bollworm, Helicoverpa armigera Hubner selected for five generations with Bacillus thuringiensis insecticidal crystal protein Cry1Ac in the laboratory developed 12.98-fold resistance. Resistance and susceptible populations were mass crossed to study the dominance of resistance. The Cry1Ac—selected (BCR) population showed 5.8-fold resistance to Cry1Aa and 5.04-fold resistance to Cry1Ab. The degree of dominance (D) was 0.34 and 0.40 for the R × S and S × R hybrids, respectively, which indicates incomplete recessive character of Cry1Ac resistance in the population. The estimated realized heritability (h ²) and response quotient (Q) of resistance for Cry1Ac were 0.52 and 0.15, respectively. This indicated the lower phenotypic variation in the selected population. The resistance risk assessment based on h ² indicated that the resistance would increased tenfold after <9 generations for Cry1Ac in the resistant population. The results show the ability of H. armigera to develop resistance against Cry1Ac and cross-resistance to Cry1Aa and Cry1Ab.     

Plant biotechnology: A case study ofBacillus thuringiensis (Bt) and its application to the future of genetic engineered trees

Agricultural productivity may be raised in a sustainable way by many different technologies such as biological fertilizers, soil and water conservation, biodiversity conservation, improved pest control, and changes in land ownership and distribution. Of these measures, biotechnology applications probably hold the most promise in augmenting conventional agricultural productivity, because biotechnology applications give not only the need to increase production, but also protect the environment and conserving natural resources for future generations. Biotechnology applications will have the possibilities to increase productivity and food availability through better agronomic performance of new varieties, including resistance to pests; rapid multiplication of disease-free plants; ability to obtain natural plant products using tissue culture; diagnosis of diseases of plants and livestock; manipulation of reproduction methods increasing the efficiency of breeding; and the provision of incentives for greater participation by the private sector through investments. Insect resistance through the transfer of a gene for resistance fromBacillus thuringiensis (Bt) is one of the most advanced biotechnology applications already being commercialized in many parts of the world. This paper reviews the development and the status ofBt technology and application ofBt transgenic plants in current agriculture, and discusses specific issues related to the transfer of the technology to the future of genetic engineered trees with emphasis on conifers. Biography: Tang Wei (1964-), male, Ph. Doctor, Research associate, Department of Biology, Howell Science Complex, East Carelina University, Greenville, NC 27858-4353, USA. Responsible editor: Chal Ruihai     

植物生物技术:苏云金杆菌抗虫基因的研究和它对未来树木遗传工程的影响

许多不同的技术可以促进农业生产力的持续增长，生物技术是其中最重要和最有前途的方法。因为生物技术不仅可以增加生产力。而且在环境和自然资源的保护中起重要作用，应用生物技术可以生产高产、优质、高抗性和无病植物，同时也可以提高育种效率和促进食品的工业化生产。苏云金杆菌抗虫基因是目前生物技术领域中应用最广泛的例子之一。由此而产生的抗虫植物正在广泛应用于世界各地的商业化生产。本文综述了苏云金杆菌抗虫基因的研究进展和它在未来林木遗传工程中的应用。表4参68。