香蕉枯萎病芽胞杆菌生防菌的筛选及其抑菌特性研究

从我国不同地区采集土样,共分离到300余株芽胞杆菌,通过平板对峙生长法从中筛选到4株对香蕉枯萎病原菌有明显拮抗作用的菌株.经16S rRNA序列分析,将这4株生防芽胞杆菌鉴定为多粘类芽胞杆菌.4株菌的生物学特性基本一致,其主要脂肪酸类型为15:0 ANTEISO,分析发现生防菌对病原菌的抑菌作用与生防菌的脂肪酸类型具有...     

原生质体融合选育耐高温耐盐红螺菌的研究

为选育耐高温耐盐红螺菌用于其粉状制剂研制,以降解水产养殖水体亚硝基氮功能达90%以上的耐盐红螺菌与能在60～70℃下生长的嗜热脂肪芽孢杆菌为出发菌株,通过正交试验探讨2种菌株的原生质体融合条件。分别对融合子进行温度、生长盐度和净化水质等功能测定,检出性能较优的融合子,同时采用电镜、细胞色素吸收光谱等方法,将融合子优良株与2种亲株进行比较鉴别。实验结果表明,2种菌株原生质体融合的最优条件为温度37℃,作用时间3 h,聚乙二醇(PEG)浓度为40%。在该优化条件下原生质体融合率为1.536%,筛选获得3株能在30～50℃良好生长的融合子(a、b、c)。融合子生长耐受温度较耐盐红螺菌亲株提高66%,但耐受盐度、降解养殖水体氨氮与亚硝基氮功能均与耐盐红螺菌亲株相近。其中融合子a菌株具有生长更快、性能更稳定的特点,其细胞形态特征、革兰氏染色属性、色素吸收峰等均与耐盐红螺菌相似。     

根瘤内生细菌对大豆胞囊线虫及根腐病菌的影响

为了明确大豆根瘤内生芽孢杆菌Snb2对大豆胞囊线虫的毒性和大豆根腐病菌的抑制作用,用菌悬液处理和对峙培养法分别测定了Snb2对两种病原微生物的作用效果.结果表明:Snb2的菌悬液能够明显抑制大豆胞囊线虫胞囊的孵化,相对抑制率达到94.9%;菌悬液处理J2 96 h时死亡率达到66.7%;Snb2菌株对4种大豆根系病原真菌表现不同程度的拮抗作用,对尖孢镰刀菌和茄腐镰刀菌的拮抗作用最明显,抑菌圈达到10 mm左右,抑制作用可持续10 d;经细菌悬浮液浸种测定,处理后的大豆子叶节到根尖的距离为9.1±4.54 cm,较对照增加了15.19%%,对幼苗生长有明显的促进作用;通过温室盆栽防效试验,进一步表明Snb2菌悬液进行种子浸种对大豆胞囊线虫病有明显的抑制作用,防治效果达到62.5%.     

海洋芽孢杆菌N11-8产蛋白酶的发酵条件优化

本研究采用响应面法(RSM)对南极海洋芽孢杆菌(Bacillus sp.)N11-8液体发酵产蛋白酶PBN11-8的发酵条件进行快速优化。通过单因素实验初步确定南极海洋芽孢杆菌N11-8产蛋白酶的最佳碳源和氮源分别为可溶性淀粉和蛋白胨;并通过Plackett-Burman(PB)设计对影响其产酶相关因素进行评估,筛选出具有显著效应的3个因素：温度、氮源和碳源;以最陡爬坡实验逼近至上述因子最大响应区域,进而采用RSM法对其最佳水平范围进行研究,确定最优发酵条件为：可溶性淀粉3 g/L,蛋白胨13.1 g/L,酵母浸粉2.9 g/L,NaCl 5 g/L,KH2PO4 1 g/L,FeCl3·6H2O 2 mmol/L,初始pH值为7.0,温度为34.0℃,转速为200 r/min,装液量为50 ml/250 ml,接种量为4%,培养时间为60 h。最终优化后的酶活达到90.5 U/ml,比初始酶活提高了23.6%。     

苏云金芽孢杆菌对黄河鲤血液免疫效果研究

研究了苏云金芽孢杆菌对黄河鲤血液免疫应答的影响.将苏云金芽孢杆菌按1.0×10~(11)、3.0×10~(11)、5.0×10~(11) cfu/kg 3个浓度添加在鱼用全价颗粒饲料中,投喂经嗜水气单胞菌疫苗免疫组(A_0～A_3)和未免疫组(B_0～B_3)黄河鲤,分别于0、15、30、40 d时检测各组黄河鲤白细胞吞噬活性、血清溶菌酶活性以及血清凝集抗体效价,并进行攻毒试验.结果表明:添加苏云金芽孢杆菌可使黄河鲤血液中白细胞吞噬活性和血清溶菌酶活性显著提高.添加组与对照组差异显著(P<0.05),添加浓度越高,血液白细胞活性和溶菌酶活性越强.免疫组与未免疫组白细胞吞噬活性差异不显著(P>0.05),而溶菌酶活性差异显著(P<0.05).在停止投喂后10 d,白细胞活性、血清溶菌酶活性逐渐下降,但差异不显著(P>0.05).添加苏云金芽孢杆菌还可提高黄河鲤的凝集抗体效价及攻毒后的存活率,其中,当菌株添加浓度为5.0×10~(11) cfu/kg时,受免疫的黄河鲤免疫保护率最高.即投喂苏云金芽孢杆菌对黄河鲤血液免疫应答有明显促进作用.     

地衣芽孢杆菌降解水产养殖中残余饵料的特性研究

从土壤及饲料添加剂中筛选获得了一株能较高效降解水产养殖中残余饵料蛋白、淀粉的功能菌,经鉴定为地衣芽孢杆菌.通过研究养殖水体中饲料浓度、pH值、温度等因素对地衣芽孢杆菌降解饲料中蛋白质、淀粉的影响.结果表明,该菌降解饲料中蛋白质、淀粉的适宜条件为:饲料浓度≤5g/L,pH值6～7,温度25～30℃,盐浓度0～1%,溶氧浓度约4mg/L.地衣芽孢杆菌在这种水体生态条件下接种5%,饲料中的蛋白质与淀粉降解率约为60%.     

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     

6~(-(2))菌的酯酶型分析和血清学鉴定

6~(-(2))菌是一株昆虫病原芽孢杆菌。经测定血清型是苏云金杆菌(Bacillus thuringensis)变种中的H_1血清型,酯酶型与已描述过的所有苏云金杆菌变种的酯酶型不同,具有特异性,是一个新的酯酶型。     

枯草芽孢杆菌TR21对香蕉抗病相关酶活的诱导作用

为筛选能显著诱导香蕉抗病相关酶活变化的枯草芽孢杆菌TR21（Bacillus subtilis）发酵液组分,并探讨其诱导香蕉抗病性机理,选择多酚氧化酶（PPO）、过氧化物酶（POD）和苯丙氨酸解氨酶（PAL）作为植物抗病性反应指标,采用灌根接种法,研究1株在大田对香蕉枯萎病具有良好防效的枯草芽孢杆菌TR21发酵液不同组分对香蕉根系内3种酶活性的影响。结果表明,接种TR21发酵液、菌体、上清和NB培养基后,香蕉根系内PPO、POD和PAL活性均比无菌水对照高,且都出现2次高峰,PPO、POD活性峰在接种后第3天和第7天出现,PAL活性峰则在接种后1天和5天时出现。比较不同组分接种处理诱导产生的酶活性强弱发现,接种TR21发酵液、菌体的3种酶活性均明显高于接种上清和NB的处理。可以判断TR21发酵液中主要有效诱导组分为菌体。灌根法接种TR21菌体后测定香蕉叶片中3种抗病酶的活性表明,菌体处理后叶片中PPO、POD和PAL活性均显著高于接种无菌水的对照,推测诱导系统抗性可能是TR21菌株防治香蕉枯萎病的机制之一。     

Bacteria inhabiting artificially inoculated xylem of Picea abies

Bacteria inhabiting the xylem of Norway spruce (Picea abies (L.) H. Karsten) were investigated. The trees had been wounded and artificially inoculated with fungi and bacteria obtained from wounds of naturally infected spruce. One and five growing seasons after inoculation the Gram‐negative bacterial population present in the stem of inoculated trees were analysed.

The Gram‐negative bacteria isolated from the trees were identified on the basis of morphological, biochemical and physiological tests and whole‐cell fatty acid composition. The predominant strains were Enterobacteriaceae fermenter strains (E. agglomerans or E. sakazakii), fluorescent and yellow pigmented Pseudomonas, Acinetobacter and Moraxella spp. All Gram‐positive bacteria were Bacillus species.

The Gram‐negative bacteria of Norway spruce differed from the Gram‐positive species in possessing stronger lipolytic activity and in their ability to utilize pine resins for growth. Gram‐positive bacteria were generally able to utilise cellulose and hemicellulose, whereas among the Gram‐negative bacteria only one xylanolytic (yellow Pseudomonas) strain was found.