对二点委夜蛾高毒力苏云金芽胞杆菌的筛选及其基因型分析

【目的】获得对二点委夜蛾Athetis lepigone(M(o|¨)schler)高毒力的苏云金芽胞杆菌(Bt)菌株,寻找对该虫具有特异杀虫活性的蛋白毒素,探索Bt菌株或其杀虫基因应用于二点委夜蛾防治的可行性。【方法】通过生物测定方法比较了36株苏云金芽胞杆菌和一株恶臭假单胞工程菌PHB-cry1Ab对二点委夜蛾幼虫的杀虫活性,同时利用PCR-RFLP方法对这些菌株的基因型进行了分析。【结果】不同Bt菌株对二点委夜蛾幼虫的杀虫活性差别很大,杀虫活性高的菌株都含有cry1Ac基因。饲毒72 h后含单基因的BtHD-73菌株(cry1Ac)对二点委夜蛾2龄幼虫的毒力(LC_(50)值为188.51μg/g)明显高于含多基因的Bt SC-40菌株(cry1Ac,cry2Ac,cry1I,vip3A)的毒力(LC_(50)值为418.13μg/g)。含有vip3A基因的Bt SC-40和BtHD-13营养期上清液对二点委夜蛾2龄幼虫表现出一定的杀虫活性(72 h死亡率分别达到42.5%和57.4%),而无vip3A基因的Bt HD-73营养期上清液未表现出明显的杀虫活性。【结论】由cry1Ac基因编码的Cry1Ac蛋白对二点委夜蛾幼虫具有特异杀虫活性,Vip3A蛋白对二点委夜蛾幼虫可能也有一定的杀虫活性。     

新vip3Aa基因的克隆、表达及其序列分析

克隆了Bt9816C的vip3A基因,并将测序结果提交到GenBank(序列号:AY945939)。该基因是一个新的vip3Aa基因,Bt杀虫晶体蛋白命名委员会将其命名为vip3Aa18。在大肠杆菌BL21中表达了该基因,生物测定结果表明纯化的Vip3Aa18蛋白对棉铃虫和甜菜夜蛾具有很高的杀虫活性。序列分析结果显示Vip3Aa18C端536至667位氨基酸残基间是一个糖类结合域,推测可能参与Vip3Aa18与敏感昆虫中肠受体结合;N端272至292位氨基酸残基间存在一个跨膜螺旋,可能与Vip3Aa18形成穿孔有关。此外,Vip3Aa18还可能具有一个二硫键。这些特殊区域和位点可能与其功能密切相关。     

苏云金芽孢杆菌营养期杀虫蛋白VIP3研究进展

的报道.本文从VIP3的类型和杀虫活性、作用机理、vip3基因的定位和分离、vip3基因重组和转vip3基因植物等方面详细介绍了VIP3近十年来的研究进展.     

Bt杀虫基因研究现状与趋势

Bt(Bacillus thuringiensis)是一种革兰氏阳性昆虫病原菌,对哺乳动物等非靶标生物安全无害,cry基因、cyt基因、vip基因编码的杀虫蛋白是其主要活性物质.目前,Bt除了用作生物杀虫剂外,表达Bt杀虫蛋白的转基因抗虫植物也已经被广泛用于害虫的防治,Bt在应用方面取得的巨大成功,极大地促进了该领域的研究发展.本文对Bt杀虫基因克隆技术、Cry蛋白结构多样性、杀虫基因命名与专利保护、研究论文发表等现状与趋势进行分析,发现我国的Bt基础研究和应用基础研究已经与国际接轨,但是产业化明显滞后,企业投入偏少.从发展趋势来看,我国在该领域仍然有较大的发展空间,参考美国转基因作物产业化与企业创新产出的时序关系,随着我国转基因作物向产业化推进,企业的研究与创新将成为一个新的增长点.     

Bt9816C培养上清中杀虫活性成分的研究

Bt9816C的培养上清对棉铃虫和甜菜夜蛾具有很高的杀虫活性。热敏实验表明β-外毒素和Zwittennicin A不是其主要杀虫活性成分。Bt9816C的无晶体株保留有卵磷酯酶C和溶血素活性,但是不再具有vip3A基因,其培养上清也丧失了杀虫活性。SDS-PAGE结果显示Bt9816C培养上清中有vip3A蛋白特征大小的89kD的蛋白,而其无晶体株正好缺失了该蛋白。以上结果表明Bt9816C培养上清中主要的杀虫活性成分是VipaA蛋白。     

苏云金杆菌辅助蛋白P20对营养期杀虫蛋白Vip3A表达的影响

为检测苏云金杆菌辅助蛋白P20对Vip3A表达和杀虫活性的影响,将p20基因与vip3A基因相连构建了重组质粒pHVP20,然后电激转化至Bt中进行了共表达,以仅携带vip3A基因的质粒pHPT3作为对照质粒。Westernblot结果显示,当vip3A基因和p20基因在Bt无晶体缺陷株CryB中共表达时,Vip3A蛋白的最大表达量约是其在CryB(pHPT3)菌株中单独表达的1.5倍。生物测定结果表明,CryB(pHVP20)和CryB(pHPT3)菌株对初孵斜纹夜蛾幼虫的LC50值分别为48.79μg/mL和78.00μg/mL,这说明P20蛋白可以促进vip3A基因在Bt中的表达,但对提高Vip3A蛋白的杀虫毒力没有显著性帮助。     

苏云金芽孢杆菌vip3A基因的鉴定、克隆及活性分析

【目的】鉴定我国自行分离的苏云金芽孢杆菌（Bacillus thuringiensis, Bt）菌株中vip3A基因的分布和基因型,从其中对鳞翅目幼虫表现高毒力的Bt菌株中克隆vip3Aa基因。【方法】利用PCR-RFLP方法确定vip3A基因的分布和鉴定基因型,利用PCR方法克隆vip3A全长基因。【结果】171株野生型Bt菌株中共鉴定出63株含有vip3A基因,均与vip3Aa1类基因相似。从TF9和Bt16菌株中克隆得到2个vip3Aa基因,分别构建了携带vip3Aa基因的表达载体p30vip-26和p30vip-27,SDS-PAGE和Western Blot分析表明,IPTG诱导后均可表达88 kDa左右的Vip3A蛋白,蛋白可溶性分析表明约10%可溶。这两种基因序列已被国际Bt基因命名委员会分别正式命名为vip3Aa26和vip3Aa27。生物测定结果显示,Vip3Aa27蛋白对粉纹夜蛾（Trichoplusia ni）、甜菜夜蛾（Spodoptera exigua）和棉铃虫（Helicoverpa armigera）3种重要鳞翅目害虫初孵幼虫的毒力较高,LC50值分别为0.125 μg/mL,0.238 μg/mL和9.238 μg/mL。而Vip3Aa26蛋白仅对粉纹夜蛾有活性,LC50值为4.423 μg/mL。【结论】本研究中的Vip3Aa27蛋白对粉纹夜蛾、甜菜夜蛾和棉铃虫幼虫均能表现高杀虫活性,而Vip3Aa26蛋白仅对粉纹夜蛾幼虫有活性,实验结果表明Vip3A蛋白个别氨基酸的变化对其杀虫活性影响很大。     

Bt9816C培养上清中杀虫活性成分的研究*

Bt98 1 6C的培养上清对棉铃虫和甜菜夜蛾具有很高的杀虫活性。热敏实验表明 β -外毒素和ZwittermicinA不是其主要杀虫活性成分。Bt981 6C的无晶体株保留有卵磷酯酶C和溶血素活性 ,但是不再具有vip3A基因 ,其培养上清也丧失了杀虫活性。SDS -PAGE结果显示Bt981 6C培养上清中有Vip3A蛋白特征大小的 89kD的蛋白 ,而其无晶体株正好缺失了该蛋白。以上结果表明Bt981 6C培养上清中主要的杀虫活性成分是Vip3A蛋白。     

一种新的Bt杀虫基因HJC原核表达蛋白活性的鉴定

HJC基因是由2个Bt基因(cry1Ab和vip3)经过人工融合而成,具有更广谱的杀虫活性,可延缓害虫产生交互抗性的时间。将已构建好的携带HJC基因的重组质粒pET28a-HJC转化到大肠杆菌BL21中诱导表达。该HJC融合蛋白主要以包涵体形式存在,变性条件下使用镍亲和层析柱对其进行纯化,并经尿素梯度透析复性后,进行免疫反应活性及美国白蛾杀虫活性测定。Western blot结果显示,该原核表达蛋白与转HJC基因水稻中的HJC蛋白有相同的免疫反应性,对美国白蛾也有一定的杀虫活性,可以替代植物外源蛋白进行转HJC基因产品的食用安全性评价。     

苏云金芽胞杆菌Vip3AaAdAa嵌合蛋白的构建及其杀虫活性分析

Vip3A类杀虫蛋白是一类新型杀虫蛋白,在氨基酸序列上与研究较为深入的Cry蛋白没有同源性,且昆虫受体结合位点与Cry蛋白也没有竞争关系。利用同源重组技术针对对甜菜夜蛾具有高活性的Vip3Aa39与无活性的Vip3Ad开展研究,成功构建了三个vip3AaAdAa型嵌合基因,将其转入大肠杆菌中表达嵌合蛋白Vip3AaAdAa1、Vip3AaAdAa2、Vip3AaAdAa3,并将这三种嵌合蛋白对甜菜夜蛾进行了杀虫活性测定。研究表明,三种嵌合蛋白对甜菜夜蛾具有杀虫活性,Vip3AaAdAa3蛋白的LC_(50)值比Vip3Aa39增加了1.4倍,Vip3AaAdAa1蛋白的LC_(50)值比Vip3Aa39增加了2.7倍,嵌合蛋白Vip3AaAdAa1和Vip3AaAdAa3的杀虫活性均低于Vip3Aa39;Vip3AaAdAa2的杀虫活性与Vip3Aa39差异不显著。     

苏云金芽孢杆菌vip3A基因的检测及保守性分析

Vip3A蛋白是苏云金芽孢杆菌(Bacillus thuringiensis,Bt)在营养期分泌的一类新型杀虫蛋白。用PCR方法从114个Bl菌株和41个Bl标准菌株中筛选到39株即约25％的菌株含有vip3A基因。利用所制备的Vip3A蛋白的多克隆抗体对以上含有vip3A基因的Bt菌株进行Western印迹分析,发现多数PCR反应为阳性的菌株都产生89kD大小的蛋白,其中有4株没有Vip3A蛋白的表达。从以上菌株中挑选2个对夜蛾科害虫具有较高和较低毒力的菌株,即S101和6ll,并分别进行vip3A基因的克隆和测序,再与GenBank上所登录的其它6个全长vip3A基因和2个已报道的但未登录GenBank的vip3A基因进行核苷酸和氨基酸序列比较,结果表明,vip3A是一个极其保守的基因。将以上所克隆的2个却3A基因即vip3A—S101和vip3A-611分别插入表达载体pQE30构建了表达质粒pOTP-S101和pOTP-6ll,转化到大肠杆菌M15,经lmmol／L IPTG诱导后均表达89kD大小的Vip3A蛋白。蛋白可溶性试验表明,Vip3A-S101和Vip3A-611分别有48％和35％的蛋白是可溶的。将Vip3A-S101和Vip3A-6ll蛋白和已报道的Vip3A—S184蛋白对初孵斜纹夜蛾(Spodoptera litura)幼虫进行生物测定,结果表明,3个Vip3A蛋白对斜纹夜蛾幼虫毒力没有显著性差异,这说明了Vip3A个别氨基酸的变化对蛋白的杀虫活性没有影响。     

Molecular characterization of a novel vegetative insecticidal protein from Bacillus thuringiensis effective against sap-sucking insect pest

Several isolates of Bacillus thuringiensis (Bt) were screened for the vegetative insecticidal protein (Vip) effective against sap-sucking insect pests. Screening results were based on LC(50) values against cotton aphid (Aphis gossypii), one of the dangerous pests of various crop plants including cotton. Among the isolates, the Bt#BREF24 showed promising results, and upon purification the aphidicidal protein was recognized as a binary toxin. One of the components of this binary toxin was identified by peptide sequencing to be a homolog of Vip2A that has been reported previously in other Bacillus spp. Vip2 belongs to the binary toxin group Vip1-Vip2, and is responsible for the enzymatic activity; and Vip1 is the translocation and receptor binding protein. The two genes encoding the corresponding proteins of the binary toxin, designated as vip2Ae and vip1Ae, were cloned from the Bt#BREF24, sequenced, and heterologously expressed in Escherichia coli. Aphid feeding assay with the recombinant proteins confirmed that these proteins are indeed the two components of the binary toxins, and the presence of both partners is essential for the activity. Aphid specificity of the binary toxin was further verified by ligand blotting experiment, which identified an ~50 kDa receptor in the brush border membrane vesicles of the cotton aphids only, but not in the lepidopteran insects. Our finding holds a promise of its use in future as a candidate gene for developing transgenic crop plants tolerant against sap-sucking insect pests.     

Expression of vip1/vip2 genes in Escherichia coli and Bacillus thuringiensis and the analysis of their signal peptides

AIMS: To determine the expression time courses and high expression level of Vip2A(c) and Vip1A(c) in Bacillus thuringiensis, and survey their insecticidal toxicity and insecticidal spectrum. METHODS AND RESULTS: A kind of new vegetative insecticidal toxin genes encoded by a single operon from B. thuringiensis had been cloned and sequenced. The individual genes, 5-terminus truncated genes and the operon were respectively expressed in Escherichia coli. Only N-terminus deleted Vip2A(c) and Vip1A(c) proteins could be purified by Ni-NTA agarose, while others were processed and their N-terminal signal peptides were cleaved. The individual genes and the operon were also expressed in B. thuringiensis. Both proteins were mostly secreted into the cell supernatants. The expression level of Vip1A(c) was influenced because of the interruption of vip2A(c) gene on the operon. Bioassays showed that neither separate protein nor both performed any toxicity against tested lepidopteran and coleopteran insects. CONCLUSIONS: Vip2A(c) and Vip1A(c) have similar secretion mechanism in E. coli and B. thuringiensis. Vip1A(c) remained its high expression level only when being expressed with vip2A(c) gene as an operon in B. thuringiensis. SIGNIFICANCE AND IMPACT OF THE STUDY: Expression of vip2A(c) and vip1A(c) genes in E. coli and B. thuringiensis were investigated. This would help to make clear the secretion mechanism of VIP proteins and study the function of ADP-ribosyltransferase Vip2.     

Characterization of a novel vip3-type gene from Bacillus thuringiensis and evidence of its presence on a large plasmid

A novel vip3-type gene named vip3LB has been isolated from Bacillus thuringiensis strain BUPM95. The corresponding secreted vegetative insecticidal protein was active against the lepidopteran insect Ephestia kuehniella. The vip3LB gene was shown, for the first time, to be carried by the large plasmid containing the cry1Ia genes of B. thuringiensis. The nucleotide sequence predicted a protein of 789 amino acids residues with a calculated molecular mass of 88.5kDa. Both nucleotide and amino acid sequences similarity analysis revealed that vip3LB is a new vip3-type gene, presenting several differences with the other vip3-type genes. Heterologous expression of the vip3LB under the control of the strong promoter P(BAD) was performed in Escherichia coli and the produced protein conferred insecticidal activity against Ephestia kuehniella. This novel vegetative insecticidal protein Vip3LB could be a very useful biological control agent.     

Characterization of Vegetative Insecticidal Protein vip Genes of Bacillus thuringiensis from Sichuan Basin in China

Vegetative insecticidal proteins (Vip), the second generation of insecticides, are produced during the vegetative growth stage of Bacillus thuringiensis (Bt). To perform a systematic study of vip genes in Bt strains from different ecological regions of Sichuan Basin, 1,789 soil samples were collected from this basin, which is situated in the western region of China. The basin has a complicated geomorphology and contains mountains, forests, highlands, hursts, and plains. A total of 2,134 Bt strains have been screened from the 1,789 soil samples. According to the results, three vip-type genes were found in this basin, namely the vip1, vip2, and vip3-type genes. Strains containing vip3-type genes were the most abundant in our collection (67.4%), followed by vip2-type genes (14.6%) and vip1-type genes (8.1%). The three types of vip genes were distributed in most of the regions, but E Mei Mountain and the Ba Lang Mountains only contained vip3 genes in environments with high elevation, low temperature, insufficient oxygen, and abundant snow. Moreover, five novel vip3 genes were found, and these Vip proteins were toxic for Chilo suppressalis. All the results mentioned above suggest that Sichuan Basin is a rich resource for vip genes.     

Isolation, characterization and expression of a novel vegetative insecticidal protein gene of Bacillus thuringiensis

Twenty-four serovars of Bacillus thuringiensis (Bt) were screened by polymerase chain reaction to detect the presence of vegetative insecticidal protein gene (vip)-like sequences by using vip3Aa1-specific primers. vip-like gene sequences were identified in eight serovars. These genes were cloned and sequenced. The deduced amino acid sequence of the vip3Aa14 gene from Bacillus thuringiensis tolworthi showed considerable differences as compared to those of Vips reported so far. The vip3Aa14 gene from Bt tolwarthi was expressed in Escherichia coli using expression vector pET29a. The expressed Vip3Aa14 protein was found in cytosolic supernatant as well as pellet fraction, but the protein was more abundant in the cytosolic supernatant fraction. Both full-length and truncated (devoid of signal sequence) Vips were highly toxic to the larvae of Spodoptera litura and Plutella xylostella. Truncation of Vip3Aa14 protein at N-terminus did not affect its insecticidal activity.     

First report of detection of the putative receptor of Bacillus thuringiensis toxin Vip3Aa from black cutworm (Agrotis ipsilon)

Black cutworm (BCW) Agrotis ipsilon, an economically important lepidopteran insect, has attracted a great attention. Bacillus thuringiensis (Bt) is spore forming soil bacteria and is an excellent environment-friendly approach for the control of phytophagous and disease-transmitting insects. In fact, bio-pesticide formulations and insect resistant transgenic plants based on the bacterium Bt delta-endotoxin have attracted worldwide attention as a safer alternative to harmful chemical pesticides. The major objective of the current study was to understand the mechanism of interaction of Bt toxin with its receptor molecule(s). The investigation involved the isolation, identification, and characterization of a putative receptor – vip3Aa. In addition, the kinetics of vip toxin binding to its receptor molecule was also studied. The present data suggest that Vip3Aa toxin bound specifically with high affinity to a 48-kDa protein present at the brush border membrane vesicles (BBMV) prepared from the midgut epithelial cells of BCW larvae.     

Bacillus thuringiensis: a biotechnology model

This paper is on the different biotechnological approaches that have been used to improve Bacillus thuringiensis (Bt) for the control of agricultural insect pests and have contributed to the successful use of this biological control agent; it describes how a better knowledge of the high diversity of Bt strains and toxins genes together with the development of efficient host-vector systems has made it possible to overcome a number of the problems associated with Bt based insect control measures. First we present an overview of the biology of Bt and of the mode of action of its insecticidal toxins. We then describe some of the progress that has been made in furthering our knowledge of the genetics of Bt and of its insecticidal toxin genes and in the understanding of their regulation. The paper then deals with the use of recombinant DNA technology to develop new Bt strains for more effective pest control or to introduce the genes encoding partial-endotoxins directly into plants to produce insect-resistant trangenic plants. Several examples describing how biotechnology has been used to increase the production of insecticidal proteins in Bt or their persistence in the field by protecting them against UV degradation are presented and discussed. Finally, based on our knowledge of the mechanism of transposition of the Bt transposon Tn4430, we describe the construction of a new generation of recombinant strains of Bt, from which antibiotic resistance genes and other non-Bt DNA sequences were selectively eliminated, using a new generation of site-specific recombination vectors. In the future, continuing improvement of first generation products and research into new sources of resistance is essential to ensure the long-term control of insect pests. Chimeric toxins could also be produced so as to increase toxin activity or direct resistance towards a particular type of insect. The search for new insecticidal toxins, in Bt or other microorganisms, may also provide new weapons for the fight against insect damage.