特异性杀虫基因Bt cry3A在桑粒肩天牛幼虫两种肠道常驻内生菌中的转化和表达

[目的]将特异性杀虫毒蛋白基因Bt cry3A转入桑粒肩天牛(Apriona germari Hope,Ag)幼虫肠道常驻内生菌中,构建能在天牛幼虫肠道中定殖并表达特异性杀虫基因Bt cry3A的工程菌.[方法]以传统方法和16S rDNA分子生物学分析等方法分离、鉴定Ag幼虫肠道优势的常驻内生菌,从中筛选出适合转化的候选菌株.利用电转化技术将含有对鞘翅目昆虫具专一性毒力Bt cry3A基因的Escherichia coli-Bacillus thuringiensis穿梭表达质粒pHT305a和pHT7911分别转入Ag幼虫肠道常驻内生菌短短芽孢杆菌(Brevibacillus brevis Ag12,Ag12)和苏云金芽孢杆菌(Bacillus thuringiensis Ag13,Ag13)中.[结果]从Ag幼虫肠道共分离获得18个不同种的可培养细菌菌株,并从中选取菌株Ag12和Ag13作为出发菌株转入Bt cry3A基因.经质粒稳定性试验、转化子生长特性测试、伴胞晶体电镜检测、毒蛋白SDS-PAGE分析、工程菌定殖性分析以及生物毒力测试,结果显示cry3A基因已经成功转入Ag幼虫的常驻内生菌短短芽孢杆菌和苏云金芽孢杆菌中,并且工程菌Ag12-305a、Ag13-305a、Ag 12-7911和Ag13-7911都能在天牛幼虫肠道内稳定生长、繁殖并表达分子量约65kDa的伴孢晶体杀虫蛋白Cry3A.[结论]Bt cry3A基因已成功转入桑粒肩天牛幼虫肠道优势常驻内生菌中,获得了四株能在桑粒肩天牛幼虫肠道内定殖,并能表达目的杀虫基因Btcry3A的转基因工程菌.     

绿色荧光蛋白基因原核表达载体的构建及其在昆虫肠道短短芽孢杆菌和苏云金芽孢杆菌中的表达

【目的】构建带有苏云金芽孢杆菌cry3a基因非芽孢依赖启动子和绿色荧光蛋白基因gfp(Green Fluorescent Protein)的原核表达载体,并转化从桑粒肩天牛幼虫肠道分离的两株常驻细菌短短芽孢杆菌CQUBb和苏云金芽孢杆菌CQUBt,以检测cry3a启动子在昆虫肠道常驻菌中的启动子活性,获得GFP标记菌株,为常驻菌在昆虫幼虫肠道中的定殖情况和杀虫工程菌的构建奠定基础。【方法】采用重叠延伸PCR将cry3a基因启动子和gfp基因进行融合,并与pHT304载体连接构建重组质粒pHT3AG,获得的重组质粒以电脉冲转化肠道常驻菌短短芽孢杆菌CQUBb和苏云金芽孢杆菌CQUBt,于可见光和荧光显微镜下观察荧光并通过SDS-PAGE分析重组菌株的蛋白表达情况,然后对重组菌株进行生长动力学分析和稳定性测试。【结果】重组菌在营养期大量组成型表达GFP,经电泳分离在凝胶上出现约29kDa的特异蛋白条带;重组菌生长曲线与出发菌没有显著差异,说明外源质粒未对宿主菌的生长带来明显不利影响;抗性条件下传代30次后两菌株外源质粒稳定性仍可达95%、67%;两个菌株比较,CQUBb比CQUBt质粒转化率高、重组菌GFP表达时间长、表达量大,并且重组菌株稳定性好。【结论】成功地将cry3a基因核心启动子和gfp基因转入桑粒肩天牛幼虫肠道常驻菌,实现了该启动子在Bt之外的菌株中发挥作用,构建了两个GFP标记菌株;重组基因工程菌株表达量大,稳定性好,可以用作昆虫肠道内微生态研究和芽孢杆菌表达系统以及杀虫菌株的构建。     

金黄色葡萄球菌OatA基因敲除菌株及其回补菌株的构建

目的:构建金黄色葡萄球菌(金葡菌)Oat A基因敲除菌株及其回补菌株。方法:以p BT2为载体,构建金葡菌Oat A基因敲除质粒p BT2-△Oat A,经金葡菌RN4220修饰后电转入金葡菌USA300,利用p BT2载体对温度敏感的特点,在42℃多次传代,筛选出金葡菌Oat A基因敲除菌株。以p LI50为载体,构建p LI50-Oat A全基因回补质粒,电转入金葡菌RN4220,再次抽提后电转入敲除菌株△Oat A,获得基因回补菌株p Oat A。结果:成功构建基因敲除质粒p BT2-△Oat A,经RN4220修饰电转入USA300,经PCR及测序鉴定,获得了金葡菌Oat A敲除菌株△Oat A。经PCR及酶切鉴定,确认p LI50-Oat A回补质粒构建成功,通过金葡菌RN4220修饰后电转入敲除菌株△Oat A,获得基因敲除回补菌株p Oat A。结论:成功构建金黄色葡萄球菌Oat A基因敲除菌株及其回补菌株,为进一步研究金葡菌Oat A的功能及其作用机制奠定基础。     

苏云金芽胞杆菌高效表达载体的构建

[目的]通过比较cry1A、cry3A、cry4A和cry8E四个基因的启动子转录活性,筛选出一个强启动子,利用强启动子构建一个苏云金芽胞杆菌(Bacillus thuringiensis,简称Bt)高效表达载体.[方法]利用启动子融合lacZ技术检测了4种启动子的转录活性.通过扫描电子显微镜观察晶体、SDS-PAGE、蛋白定量和生物活性测定等方法对新建高效表达载体进行功能验证.[结果]构建了Pcry1A、Pcry3A、Pcry4A和Pcry8E4个启动子融合报告基因lacZ的表达载体,经β-半乳糖苷酶活性分析得知,启动子活性从高到低依次为Pcry8E＞Pcry1A＞Pcry4A＞Pcry3A.选取cry8E启动子,以pHT315作为基础载体构建苏云金芽胞杆菌高效表达载体pHT315-8E21b,将cry1Ac基因连接到pHT315-8E21b和广泛应用的cry3A启动子指导的pSXY-422b上,分别转入无晶体突变株HD-73-,获得菌株HD-8E1Ac和HD-422-1Ac.扫描电子显微镜观察显示,HD-8E1Ac菌株可以形成菱形晶体,说明正确表达了cry1Ac基因.SDS-PAGE分析结合蛋白定量实验表明pHT315-8E21b表达效率高于pSXY-422b.对小菜蛾(Plutella xylostella)的生物活性测定表明HD-8E1Ac菌株对小菜蛾有生物活性,且菌株活性高于HD-422-1Ac.[结论]利用强启动子Pcry8E构建了一个能在Bt中高效表达的穿梭载体pHT315-8E21b,该载体可正确表达cry1Ac基因,其表达效率高于被广泛应用的pSXY422b.     

苏云金芽胞杆菌4.0718菌株中杀虫晶体蛋白基因的定位及鉴定

[目的]对苏云金芽胞杆菌(Bacillus thuringiensis,简称Bt)4.0718菌株中的杀虫晶体蛋白基因(insecticidal crystal protein gene,简称cry基因)进行定位和鉴定,系统分析高毒力Bt4.0718菌株的杀虫基因背景.[方法]采用脉冲电泳(PFGE)分离Bt 4.0718菌株的基因组DNA,确定该菌株的PFGE图谱和质粒图谱;采用Southern杂交分析该菌株中cry基因的定位,并使用PCR及PCR产物限制性片段长度多态性分析(PCR-RFLP)方法鉴定该菌株染色体和质粒上含有的cry基因类型.[结果]确定了Bt 4.0718菌株的PFGE图谱和质粒图潜,鉴定到Bt4.0718菌株的染色体和质粒上均定位有cry基因,且分别包含crylAa、crylAc、cry2Aa和cry2Ab 4种基因成分.但染色体上含有的cry基因可能不如质粒上含有的cry基因具有完整的开放阅渎框.[结论]首次在Bt 4.0718菌株的染色体上发现有丰富的cry基因,且与质粒上含有的cry基因类型一致.     

转化cry3A基因对苏云金芽孢杆菌YBT—803—1生长特性的影响

将携带基因cry3A的质粒通过电脉冲法转入苏云金芽孢杆菌野生菌株YBT-803-1后,对该菌的生长产生了一定的影响.结果表明,转入cry3A基因后,转化子BMBY-003的生长速度与出发菌株YBT-803-1相比虽无明显变化,但产生杀虫晶体蛋白的时间较出发菌株延迟6～8h,且最适温度提高为33℃,而对葡萄糖等14种碳源和谷氨酸等12种氮源的利用能力与出发菌株无明显差异.     

杀鞘翅目幼虫Bt菌株YM—03的δ—内毒素基因定位

苏云金芽孢杆菌（Bacillusthuringiensis）的morrisoni亚种YM－03（8a8b）是本实验室分离的对鞘翅目幼虫有高毒力的菌株。经PCR产物分析它含有cry3A基因,产生68ku的毒素蛋白。经质粒图谱分析,该菌株含有3个质粒,其大小分别为83,72,9Mu。以cry3A基因的PCR产物片段为模板标记探针,与YM－03总DNA杂交,结果显示该菌的δ－内毒素基因定位于染色体上,有望构建出稳定遗传的广谱工程菌。     

无患子内生真菌抗菌筛选与鉴定

目的筛选和鉴定具有抗菌活性的无患子内生真菌,为进一步探索其抗菌成分提供菌源。方法采用拮抗试验和体外抗菌测试方法,以大肠埃希菌(Escherichia coli)、金黄色葡萄球菌(Staphylococcus aureus)和白假丝酵母菌(Candida albicans)为指示菌,首次研究6株无患子内生真菌(HY11-1、HY11-2、P11、O、ye4、ye5)的抗菌特点。通过形态学观察和18SrDNA序列分析,对活性菌株进行菌种鉴定。结果菌株HY11-1、ye5和P11具有较强的抗菌能力,其中菌株HY11-1对金黄色葡萄球菌抑菌效果最显著,确定菌株HY11-1、ye5、P11分别为Alternaria alternate、Aspergillus ochraceus和Penicillium chrysogenum。结论 3株无患子内生真菌A.alternate HY11-1、A.ochraceus ye5和P.chrysogenum P11具有较强的抗菌效果,具有进一步研究的价值。     

B.t.c.cry 1C全长基因的克隆及其在增产菌中的表达

设计的一对引物,对苏云金芽孢杆菌科默尔亚种(Bacillus thuringiensis subsp．colmeri)15A3菌株中的cry1C基因进行PER扩增,得到包括结构基因,调节基因在内的全长为4．0kb的PCR产物。经两步克隆,将此基因连接至穿梭表达载体pHT315上,得到重组质粒pHT-1C。通过电转化将其导入一株增产菌蜡状芽孢杆菌(Bacillus cereus)9509菌株,SDS-PAGE检测到1条60kD左右的蛋白带,镜检观察到菱形晶体,生测结果表明,cry1C基因的导人使Bc9509菌株获得了对甜菜夜蛾的杀虫活性。     

明党参内生菌的分离鉴定及其对金黄色葡萄球菌的抑制作用

研究郑州市栽培明党参内生菌资源状况,筛选出对金黄色葡萄球菌具有拮抗作用的内生菌。采用平板培养法从明党参中分离内生细菌,通过混菌法和牛津杯双层平板扩散法筛选出对金黄色葡萄球菌具有明显抑制作用的菌株,并通过培养特征、形态特征、生化特征、全自动微生物质谱检测、16S rDNA基因序列分析和系统进化树分析对菌株进行了分类学鉴定。在明党参中共分离到29株内生细菌,通过初筛和复筛后,筛选出对金黄色葡萄球菌具有明显抑制作用的4株菌株NMY1、NMJ10、NMG10、PMG3,其中NMJ10对金黄色葡萄球菌的抑菌圈直径达20.3 mm,经鉴定菌株NMJ10和菌株PMG3为芽胞杆菌属新菌种(Bacillus spp.),菌株NMY1为枯草芽胞杆菌(B.subtilis),菌株NMG10为假蕈状芽胞杆菌(B.pseudomycoides)。明党参内生菌具有多样性,其中芽胞杆菌属为优势菌株,有拮抗金黄色葡萄球菌活性高的菌株存在,其代谢产物对金黄色葡萄球菌有较高抑制作用,为抗菌药源成分的开发提供了新的来源。     

Improvement of Bacillus sphaericus toxicity against dipteran larvae by integration, via homologous recombination, of the Cry11A toxin gene from Bacillus thuringiensis subsp. israelensis.

Integrative plasmids were constructed to enable integration of foreign DNA into the chromosome of Bacillus sphaericus 2297 by in vivo recombination. Integration of the aphA3 kanamycin resistance gene by a two-step procedure demonstrated that this strategy was applicable with antibiotic resistance selection. Hybridization experiments evidenced two copies of the operon encoding the binary toxin from B. sphaericus in the recipient strain. The Bacillus thuringiensis subsp. israelensis cry11Aal gene (referred to as cry11A), encoding a delta-endotoxin with toxicity against Culex, Aedes, and Anopheles larvae, was integrated either by a single crossover event [strain 2297 (::pHT5601), harboring the entire recombinant plasmid] or by two successive crossover events [strain 2297 (::cry11A)]. The level of the Cry11A production in B. sphaericus was high; two crystalline inclusions were produced in strain 2297 (::pHT5601). Synthesis of the Cry11A toxin conferred toxicity to the recombinant strains against Aedes aegypti larvae, for which the parental strain was not toxic. Interestingly, the level of larvicidal activity of strain 2297 (::pHT5601) against Anopheles stephensi was as high as that of B. thuringiensis subsp. israelensis and suggested synergy between the B. thuringiensis and B. sphaericus toxins. The toxicities of parental and recombinant B. sphaericus strains against Culex quinquefasciatus were similar, but the recombinant strains killed the larvae more rapidly. The production of the Cry11A toxin in B. sphaericus also partially restored toxicity for C. quinquefasciatus larvae from a population resistant to B. sphaericus 1593. In vivo recombination therefore appears to be a promising approach to the creation of new B. sphaericus strains for vector control.     

Characterization of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> Strain DOR4 Toxic to Castor Semilooper <Emphasis Type="Italic">Achaea janata</Emphasis>: Proteolytic Processing and Binding of Toxins to Receptors

We have isolated a strain of Bacillus thuringiensis (Bt) from Indian soil samples that was shown to be toxic to Achaea janata larvae. The isolate, named B. thuringiensis DOR4, serotypically identified with the standard subspecies kurstaki (H3a3b3c) and produced bipyramidal inclusions along with an amorphous type. Although the plasmid pattern of DOR4 was different from that of the reference strain, a crystal protein profile showed the presence of two major bands (130 and 65 kDa) similar to those of Bt subsp. kurstaki HD-1. To verify the cry gene content of DOR4, triplex PCR analysis was performed; it showed amplification of the cry1C gene in addition to cry1Aa, cry1Ac, cry2A, and cry2B genes, but not the cry1Ab gene. RT-PCR analysis showed the expression of cry1Aa and cry1Ac genes. In vitro proteolysis of DOR4 protoxin with midgut extract generated products of different sizes. Zymogram analysis of DOR4 protoxin as substrate pointed to a number of distinct proteases that were responsible for activation of protoxins. Furthermore, toxin overlay analysis revealed the presence of multiple toxin-binding proteins in midgut epithelium. Based on all these characterizations, we suggest that the Bt DOR4 strain can be exploited for an A. janata control program.     

苏云金芽胞杆菌杀虫晶体蛋白基因cry1Ab16的克隆及表达

通过对已知cry1类基因以及已发表的cry1Ab的序列进行分析,分别设计了引物P1、P2、P3和P4,首次从无晶体的芽胞杆菌AC11中扩增到一个苏云金芽胞杆菌杀虫晶体蛋白（Insecticidal crystal protein, ICP）cry1Ab类基因。测序结果显示该基因与已知的cry1Ab1基因有8个核苷酸不同,编码的蛋白有7个氨基酸差异。此基因已登录GenBank,并命名为新亚型基因cry1Ab16 (Ac. NO. AF375608)。Southern杂交结果进一步证实该基因存在于菌体的质粒上。将cry1Ab16基因克隆到Escherichia coli表达载体pQE30上并转化E. coli M15。Western印迹分析表明,E. coli M15表达了130 kD的Cry1Ab16蛋白,但此蛋白不稳定,大部分降解成65 kD的蛋白。将表达Cry1Ab16 蛋白的大肠杆菌用涂布法对三龄小菜蛾（Plutella xylostella）毒力测定,其LC50为258.3mg/L;对其他夜蛾科害虫的生长发育也有明显的抑制作用。     

Constructing Bacillus thuringiensis strain that co-expresses Cry2Aa and chitinase

A triple recombineering technique was used with plasmid pHT315 to produce pHTEC, a construct carrying chitinase and cry2Aa genes from Bacillus thuringiensis subsp. kurstaki 4.0718. Transformation of wild-type B. thuringiensis strain HD73 and the acrystalliferous strain Cry-B with pHTEC resulted in the recovery of recombinant strains that expressed Cry2Aa as cubic crystals in the cell pellet and soluble chitinase protein. The toxicity of HD73 (pHTEC) against Helicoverpa armigera larvae increased sevenfold when compared with HD73 (pHT315) harboring pHT315 vector. The triple recombineering protocol was optimized by comparing recombination efficacy mediated by RecE/RecT and Redα/Redβ and by using single-strand DNA as substrate.     

苏云金芽孢杆菌B-Pr-88菌株中cry2Ab4基因的表达和杀虫活性研究

以我室自行分离的对鳞翅目夜蛾科害虫具有高毒力的Bt菌株B-Pr-88为材料,用PCR-RFLP方法从其质粒DNA文库中筛选到含cry2Ab基因的一个阳性克隆pZF858,序列测定发现,该片段含有cry2Ab全长基因,开放读码框为1902bps,编码由633个氨基酸组成的70.7kD蛋白,氨基酸同源性与已公布的cry2Ab基因同源性均为99.8%,经Bt基因国际命名委员会正式命名为cry2Ab4。根据cry2Ab4基因开放阅读框架(ORF)两端序列,设计合成一对特异引物L2ab5和L2ab3,PCR扩增获得cry2Ab4完整ORF,与大肠杆菌表达载体pET-21b连接,构建了重组表达质粒pET-2Ab4,质粒导入大肠杆菌BL21(DE3),IPTG诱导后,SDS-PAGE电泳证实该基因表达了60kD的蛋白,生物测定表明,Cry2Ab4对棉铃虫和大豆食心虫具有高毒力,同时对小菜蛾和二化螟有一定的杀虫活性,而对亚洲玉米螟和甜菜夜蛾没有杀虫活性。     

<Emphasis Type="Italic">In vivo</Emphasis> fluorescence observation of parasporal inclusion formation in <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

A recombinant gene expressing a Cry1Ac-GFP fusion protein with a molecular mass of approximately 160 kD was constructed to investigate the expression of cry1Ac, the localization of its gene product Cry1Ac, and its role in crystal development in Bacillus thuringiensis. The cry1Ac-gfp fusion gene under the control of the cry1Ac promoter was cloned into the plasmid pHT304, and this construct was designated pHTcry1Ac-gfp. pHTcry1Ac-gfp was transformed into the crystal-negative strain, HD-73 cry⁻, and the resulting strain was named HD-73⁻(pHTcry1Ac-gfp). The gfp gene was then inserted into the large HD-73 endogenous plasmid pHT73 and fused with the 3′ terminal of the cry1Ac gene by homologous recombination, yielding HD-73Φ(cry1Ac-gfp)3534. Laser confocal microscopy and Western blot analyses showed for the first time that the Cry1Ac-GFP fusion proteins in both HD-73⁻(pHTcry1Ac-gfp) and HD-73Φ(cry1Ac-gfp)3534 were produced during asymmetric septum formation. Surprisingly, the Cry1Ac-GFP fusion protein showed polarity and was located near the septa in both strains. There was no significant difference between Cry1Ac-GFP and Cry1Ac in their toxicity to Plutella xylostella larvae.