利用双T-DNA载体系统培育无选择标记转基因烟草

建立了一种利用双T-DNA载体培育无选择标记转基因植物的方法。通过体外重组构建了双T-DNA双元载体pDLBRBbarm。载体中,选择标记nptⅡ基因和另一代表外源基因的bar基因分别位于2个独立的T-DNA。利用农杆菌介导转化烟草(Nicotiana tabacum L.),在获得的转化植株中,同时整合有nptⅡ基因和bar基因的频率为59．2％。对4个同时整合有nptⅡ和bar基因植株自交获得的T1代株系进行检测分析,发现在3个T1代株系2个T-DNA可以发生分离,其中约19．5％的转基因T1代植株中只存在bar基因而不带选择标记nptⅡ。这一结果说明双T-DNA载体系统能有效地用于培育无选择标记的转基因植物。研究还利用位于2个不同载体上的nptⅡ基因与bar基因通过农杆菌介导共转化烟草,获得共转化植株的频率为20．0％～47．4％,低于使用双T-DNA转化的共转化频率。     

利用双T-DNA载体系统培育无选择标记转基因烟草

建立了一种利用双T-DNA载体培育无选择标记转基因植物的方法.通过体外重组构建了双T-DNA双元载体pDLBRBbarm.载体中,选择标记nptⅡ基因和另一代表外源基因的bar基因分别位于2个独立的T-DNA.利用农杆菌介导转化烟草(Nicotiana tabacum L.),在获得的转化植株中,同时整合有nptⅡ基因和bar基因的频率为59.2%.对4个同时整合有nptⅡ和bar基因植株自交获得的T1代株系进行检测分析,发现在3个T1代株系2个T-DNA可以发生分离,其中约19.5%的转基因T1代植株中只存在bar基因而不带选择标记nptⅡ.这一结果说明双T-DNA载体系统能有效地用于培育无选择标记的转基因植物.研究还利用位于2个不同载体上的nptⅡ基因与 bar基因通过农杆菌介导共转化烟草,获得共转化植株的频率为20.0%～47.4%,低于使用双T-DNA转化的共转化频率.     

通过构建三段T-DNA载体高频率获得无标记转基因大豆植株的研究

高频率获得无选择标记转基因植株有利于转基因植物的环境释放和安全性生产,农杆菌介导的共转化法是获得无标记转基因植株的方法之一。含二段T-DNA载体的共转化法已被人们成功应用,而二段以上T-DNA载体的共转化法还未见报道。基于这一目的,通过几个中间质粒构建了含有三段T-DNA的双元表达载体pNB35SVIP1,其中包含1个拷贝bar基因选择标记基因表达盒和2个拷贝VIP1目的基因表达盒。利用EHA101农杆菌菌系介导法转化大豆子叶节,经过在含3~5mg/Lglufosinate培养基上多次筛选,获得了一定数量抗性再生植株,然后对抗性再生植株进行叶片涂抹除草剂、Southernblot和Northernblot检测,共鉴定出51棵T0代转基因植株,转化频率0·83%~3·16%,二个基因的共转化频率为86·4%。在对T1代群体进行叶片涂抹除草剂检测的基础上,不抗除草剂植株进行PCR、Southernblot和Northernblot检测,共鉴定出41棵无选择标记转基因植株,无标记植株获得率为7·6%。检测结果还表明,T1代群体中22·7%的株系发生了基因丢失现象,27·3%的株系发生了bar基因沉默现象,目的基因在37·1%的无标记植株中发生了沉默现象。三段T-DNA的双元表达载体是获得无标记转基因植株的理想途径。     

β-甘露聚糖酶基因在野生酵母菌中的整合诱导型表达

目的:实现β-甘露聚糖酶基因在野生酵母菌中的整合诱导型表达。方法:克隆猪肠道野生酵母菌JSY4的25S rDNA片段;并与YIP5经EcoRⅠ与BamHⅠ双酶切连接,构建载体YIP5-rDNA。BamHⅠ与SalⅠ双酶切YIP5-rDNA,EcoRⅠ与SalⅠ双酶切pGEM-ManⅠ得到ManⅠ基因,BglⅡ与EcoRⅠ双酶切pPIC9K得到AOX1启动子,将三个片段连接,构建高拷贝整合诱导型表达载体YIP5-rDNA-AOX1-ManⅠ。提取DNA用SalⅠ单酶切线性化与pAX15按3∶1的比例共转化JSY4,在含300μg/mlG418的YEPD平板上筛选工程菌转化子,PCR方法鉴定。用2%甲醇诱导共转化工程菌以实现表达。结果:成功表达出β-甘露聚糖酶,其比活力为0.90IU/ml。而且传代10次后仍能检测到ManⅠ基因的表达产物β-甘露聚糖酶。结论:实现了β-甘露聚糖酶基因随共转化工程菌染色体稳定遗传及表达的目的。     

大白菜抗软腐病基因BrWRKY33植物表达载体的构建

利用农杆菌侵染法获得抗软腐病转BrWRKY33基因大白菜,首先要构建植物表达载体。本实验根据BrWRKY33基因的序列及pROK2表达载体的酶切位点设计引物(FN/RN),获得BrWRKY33基因,然后将该基因连接到克隆载体pGEM-TEasy,重新构建了克隆载体T-WRKY。经测序及酶切验证,选取PCR反应中错配率最低的产物,构建了表达载体pROK2-WRKY,并将该表达载体转入到根癌农杆菌EHA105中,并对其转化子进行了鉴定。结果表明,PCR扩增获得目的基因BrWRKY33全长约1443bp,PCR及酶切结果鉴定表明克隆载体T-WRKY已经重新构建成功。表达载体的PCR及BamHⅠ和KpnⅠ双酶切鉴定表明有4个重组子表现阳性,表明目的基因已经插入到pROK2表达载体,表达载体构建成功。PCR鉴定表明表达载体pROK2-WRKY已经转入根癌农杆菌EHA105中。本实验结果将为进一步研究大白菜抗软腐病基因的转化奠定基础。     

一种新型巴斯德毕赤酵母表达载体的构建及甘露聚糖酶的表达

目的:构建以带自身启动子的蔗糖转化酶基因(suc2)为选择标记的载体,用于外源基因在巴斯德毕赤酵母中的正确分泌表达。方法:根据已发表的蔗糖转化酶基因序列设计并合成1对引物,应用PCR技术,以啤酒酵母INVSC1总DNA为模板,扩增出包含自身启动子和终止区序列的suc2基因。将该基因与毕赤酵母表达载体pPIC9K连接,构建了以suc2为选择标记的表达载体pPIC12K。将甘露聚糖酶基因man克隆入载体pPIC12K,用PEG/LiCl法转化毕赤酵母GS115菌株。以蔗糖为惟一碳源筛选转化子,利用底物平板检测筛选到的转化子中man基因的表达,并对重组表达菌株进行连续传代实验。结果:部分转化子周围产生明显的水解圈,证明甘露聚糖酶已经得到分泌表达;对重组表达菌株的连续传代实验证实了该表达载体具有良好的遗传稳定性。结论:以带自身启动子的suc2基因为选择标记的表达载体构建成功,并且这个新型表达载体能够对外源基因进行稳定有效的分泌表达。     

通过构建三段T-DNA载体高频率获得无标记转基因大豆植株的研究

高频率获得无选择标记转基因植株有利于转基因植物的环境释放和安全性生产,农杆菌介导的共转化法是获得无标记转基因植株的方法之一。含二段T-DNA载体的共转化法已被人们成功应用,而二段以上T-DNA载体的共转化法还未见报道。基于这一目的,通过几个中间质粒构建了含有三段T-DNA的双元表达载体pNB35SVIP1,其中包含1个拷贝bar基因选择标记基因表达盒和2个拷贝VIP1目的基因表达盒。利用EHA101农杆菌菌系介导法转化大豆子叶节,经过在含3～5mg/L glufosinate培养基上多次筛选,获得了一定数量抗性再生植株,然后对抗性再生植株进行叶片涂抹除草剂、Southern blot和Northern blot检测,共鉴定出51棵T₀代转基因植株,转化频率0.83%～3.16%,二个基因的共转化频率为86.4%。在对T₁代群体进行叶片涂抹除草剂检测的基础上,不抗除草剂植株进行PCR、Southern blot和Northern blot检测,共鉴定出41棵无选择标记转基因植株,无标记植株获得率为7.6%。检测结果还表明,T₁代群体中22.7%的株系发生了基因丢失现象,27.3%的株系发生了bar基因沉默现象,目的基因在37.1%的无标记植株中发生了沉默现象。三段T-DNA的双元表达载体是获得无标记转基因植株的理想途径     

三个方便实用的植物表达载体构建与验证

为满足植物功能基因组学研究及转基因安全性需要,本研究根据一些国内外引进或商业化的植物表达载体及其相关元件,构建了3个适合于植物,尤其是单子叶植物转化的表达载体,即p AH006、p WMB022和p WMB025。p AH006载体包含由玉米泛素ubi启动子调控的GUS基因和bar基因的完整T-DNA区域,此区段能够被酶切回收,可用于单子叶植物农杆菌介导转化效率评价及基因枪介导线状DNA转化效果研究;p WMB022载体携带由双35S启动子调控的玉米色素基因Lc和C1,可用作基因枪介导的共转化筛选标记,直观筛选含目标基因转基因材料;p WMB025载体携带由ubi启动子调控的、商业化转基因植物中广泛利用的EPSPS基因,可用于禾谷类作物农杆菌或基因枪介导的遗传转化,载体多克隆位点可通过酶切方式更换目标基因。酶切鉴定结合农杆菌或基因枪介导的小麦幼胚愈伤组织或叶片转化验证此3个载体表明,载体构建正确,其标记基因、可视化基因和报告基因均能正常表达。这3个载体的构建对于小麦等植物转化效率提升、安全型转基因作物获得和植物功能基因组学研究等具有重要意义。     

获得多价转基因作物的策略

本探讨了在利用植物基因工程技术的基础上,通过构建多基因或多个表达载体,进行一次,多次基因转化或共转化方法获得转多价基因作物的一些策略,并进行了展望。     

人BMP4基因的克隆及其原核表达载体的构建

以成熟人胎盘组织为材料来源,克隆人BMP-4基因的全长cDNA,经过PCR扩增后与pMD18-T载体连接,构建pMD18-T-BMP4克隆质粒.酶切后回收小片段与表达载体pET-22b的多克隆酶切位点连接,构建原核表达载体pET22b-BMP4,酶切及测序鉴定重组子.重组质粒转化至感受态的Rosseta宿主菌,经IPTG诱导表达,SDS-PAGE检测蛋白表达情况.结果显示,从胎盘组织中成功地克隆到人BMP4基因,与NCBI中公布的序列100％相符合,原核表达载体pET22b-BMP4转化至Rosseta构建表达菌体,经IPTG诱导后电泳分析可见重组蛋白表达的条带.     

双歧杆菌质粒聚合酶基因对质粒载体稳定性的影响

目的探讨双歧杆菌天然质粒的聚合酶基因（Bifidobacterium plasmid polymerase,BPP）对人工构建的大肠埃希菌～双歧杆菌穿梭质粒载体（shuttle vector）在长双歧杆菌中稳定性的影响。方法首先电转化质粒pBADs—A和pBADs-BPP至长双歧杆菌,培养鉴定后,接种含质粒pBADs—A和pBADs-BPP的双歧杆菌于AMP^-和AMP^＋的MRS培养液中。厌氧培养后,将样品涂布于AMP^＋的MRS固体培养板上计数菌落数。结果相同条件下质粒pBADs·BPP组菌落数高于质粒pBADs—A组（P〈0．05）。结论BPP可以增加质粒载体的稳定性。     

Partition-mediated plasmid pairing

Plasmid partition systems are essential for the stability and thus the survival of low-copy-number plasmids in growing bacterial populations. The partition reaction is responsible for proper intracellular distribution of plasmids in the bacterial cell cycle. One common step in most partition models is the pairing of plasmids to each other by partition components. Here, evidence that supports the pairing of plasmids via their partition complexes is reviewed, and discussed in light of recent observations that many plasmids, including those without active partition systems are clustered in limited groups inside bacterial cells.     

Bacterial plasmid stability

Bacterial plasmids are ubiquitous ‘minichromosomes’ that have major importance in clinical microbiology, as agents of pathogenicity and as carriers of antibiotic resistance, and in molecular genetics, through their role as vectors in gene manipulation. Plasmids carry a wide range of dispensable, transiently useful and often bizarre functions.¹ Naturally occurring plasmids, in addition to modifying the host cell phenotype, carry genes involved in the control of their own vegetative replication, plasmid copy number² and stable inheritance. They may also carry determinants for the conjugal transfer of DNA between bacteria.³ Whereas low-copy-number plasmids must be partitioned by some active process during cell division, the evidence suggests that multicopy plasmids are distributed randomly between daughter cells. Two independent determinants are necessary for the stable inheritance of multicopy plasmids, and both of these appear to act by maximizing the number of independent plasmid molecules.     

On plasmid incompatibility

In this paper is presented a brief review of the current state of information on plasmid incompatibility followed by a detailed mathematical model dealing with incompatibility between autonomous homogenic plasmids and based on the assumption that the intracellular plasmid copy pool is randomized with respect to assortment during cell division. Two cases are considered: one in which each plasmid copy replicates once in each generation of cell growth (regular replication) and one in which plasmids are chosen at random for replication from a common pool, irrespective of their replication history (random replication). In both cases, it is assumed that the partition of plasmid copies to daughter cells at cell division is regular—existing plasmid copies are divided equally among the two daughter cells (equipartition). In the case of regular replication coupled with equipartition, it is shown that the survival of heteroplasmid cells (cells containing at least one copy of each of two incompatible plasmids) during exponential growth in a nonselective medium is given by H = H₀[1 − 1/(2N − 1)]ⁿ, where H₀ and H are the numbers of heteroplasmid cells after 0 and n generations of growth, respectively, and N is the plasmid copy number in newborn cells. In the second case, (random replication-equipartition), it is shown that the survival of the heteroplasmid population during exponential growth under nonselective conditions is given by H = H₀[(N − 1)(2N + 1)/(2N − 1)(N + 1)ⁿ. Sample calculations are presented to show that segregation is more rapid in the latter than in the former case. Finally, some of the plasmid-linked genetic determinants that might be expected to affect the expression of incompatibility between nonisogenic plasmids are briefly considered. These determinants include recognition specificity for replication origins, recognition specificity, specific activity of copy number control systems, and recognition specificity of partition systems.     

Curing of plasmid pXO1 from Bacillus anthracis using plasmid incompatibility

The large plasmid pXO1 encoding the anthrax toxin is important for the virulence of Bacillus anthracis. It is essential to cure pXO1 from B. anthracis to evaluate its role in the pathogenesis of anthrax infection. Because conventional methods for curing plasmids (e.g., curing agents or growth at elevated temperatures) can induce mutations in the host chromosomal DNA, we developed a specific and reliable method to eliminate pXO1 from B. anthracis using plasmid incompatibility. Three putative replication origins of pXO1 were inserted into a temperature-sensitive plasmid to generate three incompatible plasmids. One of the three plasmids successfully eliminated the large plasmid pXO1 from B. anthracis vaccine strain A16R and wild type strain A16. These findings provided additional information about the replication/partitioning of pXO1 and demonstrated that introducing a small incompatible plasmid can generate plasmid-cured strains of B. anthracis without inducing spontaneous mutations in the host chromosome.     

Adaptive plasmid evolution results in host-range expansion of a broad-host-range plasmid

Little is known about the range of hosts in which broad-host-range (BHR) plasmids can persist in the absence of selection for plasmid-encoded traits, and whether this "long-term host range" can evolve over time. Previously, the BHR multidrug resistance plasmid pB10 was shown to be highly unstable in Stenotrophomonas maltophilia P21 and Pseudomonas putida H2. To investigate whether this plasmid can adapt to such unfavorable hosts, we performed evolution experiments wherein pB10 was maintained in strain P21, strain H2, and alternatingly in P21 and H2. Plasmids that evolved in P21 and in both hosts showed increased stability and decreased cost in ancestral host P21. However, the latter group showed higher variability in stability patterns, suggesting that regular switching between distinct hosts hampered adaptive plasmid evolution. The plasmids evolved in P21 were also equally or more stable in other hosts compared to pB10, which suggested true host-range expansion. The complete genome sequences of four evolved plasmids with improved stability showed only one or two genetic changes. The stability of plasmids evolved in H2 improved only in their coevolved hosts, not in the ancestral host. Thus a BHR plasmid can adapt to an unfavorable host and thereby expand its long-term host range.     

Incompatibility between a Rhizobium Sym plasmid and a Ri plasmid of Agrobacterium

The symbiotic plasmid of Rhizobium trifolii G1008 was mobilized to other Rhizobium strains and to Agrobacterium using Tn5-Mob, a transposon that confers on a host replicon the ability to be mobilized in trans by RP4. Incompatibility was observed between pSymG1008 and the hairy-root-inducing plasmid pRi1855. Agarose gel electrophoresis revealed that pRi1855 was eliminated as an autonomous element in the presence of pSymG1008 and its absence was correlated with loss of the ability to induce hairy root disease. This indicates a close ancestral relationship between a Rhizobium symbiotic plasmid and a plant pathogenic plasmid of Agrobacterium. pSymG1008 and pRi1855 can be assigned to the IncRh-3 incompatibility group. Furthermore, pSymG1008 was mobilized at low frequency to R. phaseoli 51E and the transconjugants isolated had lost the indigenous Sym plasmid and the ability to nodulate beans.     

Nif plasmid from Lignobacter

Lignobacter strain K17 is able to degrade aromatic compounds and to fix atmospheric nitrogen. It was proved that capacity for nitrogen fixation by Lignobacter was plasmid mediated. Plasmid pUCS100 (17.5 Mdal) carrying nif genes was transferred from Lignobacter to Escherichia coli SK1592 and Salmonella typhimurium. The transposon Tn9 was translocated to pUCS100 to facilitate selection of Nif⁺ bacteria. E. coli SK1592 harboring the new plasmid (pUCS101) reduced acetylene under anaerobic conditions. Plasmids pUCS100 and pUCS101 were not stably maintained in E. coli and S. typhimurium.Abbreviations Mdal megadalton - CsCl-EtBr caesium chloride ethidium bromide - m.o.i. multiplicity of infection     

The repABC plasmid family

repABC plasmids are widely distributed among alpha-proteobacteria. They are especially common in Rhizobiales. Some strains of this bacterial order can contain multiple repABC replicons indicating that this plasmid family includes several incompatibility groups. The replication and stable maintenance of these replicons depend on the presence of a repABC operon. The repABC operons sequenced to date share some general characteristics. All of them contain at least three protein-encoding genes: repA, repB and repC. The first two genes encode proteins involved in plasmid segregation, whereas repC encodes a protein crucial for replication. The origin of replication maps within the repC gene. In contrast, the centromere-like sequence (parS) can be located at various positions in the operon. In this review we will summarize current knowledge about this plasmid family, with special emphasis on their structural diversity and their complex genetic regulation. Finally, we will examine some ideas about their evolutionary origin and trends.