利用TA克隆的方法简便构建入门克隆

Gateway技术是一种通用型克隆方法,其基于λ噬菌体位点特异性重组,将目的DNA快速克隆到各种与Gateway技术兼容的目的载体上,不需要进行酶切和连接反应。但存在获得入门克隆过程中相关反应酶制剂价格昂贵,且药品订购时间较长等问题。通过对入门载体pDONR207的改造,使之产生3’端具有单个T 末端的线性化的入门载体,采用TA克隆的方法替代BP反应,从而简便、经济和快速地获得入门克隆。利用改造后的Gateway技术构建拟南芥SOS2基因的原核表达载体和真核表达载体,通过原核表达和原生质体瞬时表达证明通过此方法构建的表达载体在原核细胞和真核细胞中都得到了很好的表达。     

T载体介导的基于attL核心区LR反应的简化快速Gateway克隆系统

Gateway克隆技术已得到广泛的应用。该技术先通过BP反应将目标片段连到带有完整attL特异识别位点的入门载体,然后与终载体通过LR反应得到表达载体。Gateway克隆方法与传统的酶切连接方法相比有快速简单等优点。但是,BP和LR酶都非常昂贵。本研究首先对3个常用Gateway载体的atts特异位点序列比对发现,attL序列核心交换位点“core attL”的21~22 bp长的碱基是保守和必要的。由此,设计含有core-attL序列的引物,通过PCR克隆得到DNA片段并连入pMD18-T载体,然后进行LR反应,可成功得到目标表达载体,并在保守的位点上正确重组。本研究还对其中一个带有绿色荧光蛋白基因的表达载体转化至烟草,能够正常表达该蛋白质。结果表明,通过将含有attL核心位点基因片段连接到pMD18-T载体上,可以省略BP反应而将目标片段连接到终载体上,节约了反应时间和成本。     

A Gateway MultiSite recombination cloning toolkit

The generation of DNA constructs is often a rate-limiting step in conducting biological experiments. Recombination cloning of single DNA fragments using the Gateway system provided an advance over traditional restriction enzyme cloning due to increases in efficiency and reliability. Here we introduce a series of entry clones and a destination vector for use in two, three, and four fragment Gateway MultiSite recombination cloning whose advantages include increased flexibility and versatility. In contrast to Gateway single-fragment cloning approaches where variations are typically incorporated into model system-specific destination vectors, our Gateway MultiSite cloning strategy incorporates variations in easily generated entry clones that are model system-independent. In particular, we present entry clones containing insertions of GAL4, QF, UAS, QUAS, eGFP, and mCherry, among others, and demonstrate their in vivo functionality in Drosophila by using them to generate expression clones including GAL4 and QF drivers for various trp ion channel family members, UAS and QUAS excitatory and inhibitory light-gated ion channels, and QUAS red and green fluorescent synaptic vesicle markers. We thus establish a starter toolkit of modular Gateway MultiSite entry clones potentially adaptable to any model system. An inventory of entry clones and destination vectors for Gateway MultiSite cloning has also been established (www.gatewaymultisite.org).     

使用与Gateway技术兼容的T载体获得入门克隆

与Gateway技术兼容的农杆菌双元载体系统已开始应用于植物功能基因组的研究,但应用这些载体系统的一个瓶颈问题,是如何简单、经济和高效地将PCR产物或其他来源的目的DNA片段构建到入门载体上获得入门克隆.为此,将传统的TA克隆技术与Gateway重组克隆技术进行整合,构建了与Gateway技术兼容的两种TA克隆载体,用于在克隆PCR产物或其他来源的目的DNA片段的同时获得入门克隆.利用兼容Gateway技术的TA克隆载体有效地解决了上述瓶颈问题.     

A Versatile Zero Background T-Vector System for Gene Cloning and Functional Genomics

With the recent availability of complete genomic sequences of many organisms, high-throughput and cost-efficient systems for gene cloning and functional analysis are in great demand. Although site-specific recombination-based cloning systems, such as Gateway cloning technology, are extremely useful for efficient transfer of DNA fragments into multiple destination vectors, the two-step cloning process is time consuming and expensive. Here, we report a zero background TA cloning system that provides simple and high-efficiency direct cloning of PCR-amplified DNA fragments with almost no self-ligation. The improved T-vector system takes advantage of the restriction enzyme XcmI to generate a T-overhang after digestion and the negative selection marker gene ccdB to eliminate the self-ligation background after transformation. We demonstrate the feasibility and flexibility of the technology by developing a set of transient and stable transformation vectors for constitutive gene expression, gene silencing, protein tagging, protein subcellular localization detection, and promoter fragment activity analysis in plants. Because the system can be easily adapted for developing specialized expression vectors for other organisms, zero background TA provides a general, cost-efficient, and high-throughput platform that complements the Gateway cloning system for gene cloning and functional genomics.     

An in vitro recombination method to convert restriction- and ligation-independent expression vectors

In recent years, restriction-less recombination cloning systems based on site-specific recombinase with high efficiency have been proven to be very successful. Thus, it is desirable to convert existing conventional vectors to recombination vectors. In this report, we describe the conversion of a set of widely used conventional vectors to Gateway recombination expression vectors. An attB cassette flanked by several restriction enzyme sites was inserted in a cloning vector, and then subcloned into existing vectors to be converted to construct intermediate vectors containing the attB cassette, which were then converted to recombination expression vectors by in vitro recombination. The intermediate vectors generated in this study can be used for releasing the attB cassette to convert other vectors using the same protocol described here. With the increasing number of recombination vectors constructed with this protocol, the likeliness of releasing the attB cassette from an existing vector, rather than synthesizing it with PCR, will increase. The final expression vectors can also be used for releasing the attR cassette for constructing new vectors.     

Gateway技术构建交链孢菌JH505 cDNA文库

Gateway(R)技术构建Cdna文库,利用λ噬菌体的位点特异性重组,避免使用限制性内酶切割Cdna,能够解决常规方法构建Cdna文库的技术缺陷.首次应用Gateway(R)技术构建交链孢菌Cdna文库,经检测Cdna入门文库的滴度达到1×107cfu/Ml,文库总容量为9×107cfu,平均插入片段为1510bp.通过LR重组把入门文库转换为表达文库,表达文库的滴度为1.58×106cfu/Ml,文库总容量为6.32×106cfu,平均插入片段大小为1680bp.表达文库的构建为进一步克隆植物激活蛋白基因打下了基础.     

High efficiency single step production of expression plasmids from cDNA clones using the Flexi Vector cloning system

The success of structural genomics and proteomics initiatives is dependent on the availability of target genes in vectors suitable for protein production. Here, we compare two high-throughput methods for producing expression vectors from plasmid-derived cDNA fragments. Expression vectors were constructed for compatibility with the Gateway recombination cloning system and the Flexi Vector restriction-based cloning system. Cloning protocols for each system were conducted in parallel for 96 different target genes from PCR through the production of sequence-verified expression clones. The short nucleotide sequences required to prepare the target open reading frames for Flexi Vector cloning allowed a single-step PCR protocol, resulting in fewer mutations relative to the Gateway protocol. Furthermore, through initial cloning of the target open reading frames directly into an expression vector, the Flexi Vector system gave time and cost savings compared to the protocol required for the Gateway system. Within the Flexi Vector system, genes were transferred between four different expression vectors. The efficiency of gene transfer between Flexi Vectors depended on including a region of sequence identity adjacent to one of the restriction sites. With the proper construction in the flanking sequence of the vector, gene transfer efficiencies of 95-98% were demonstrated.     

一种高效低背景T载体的构建

介绍一种构建高效低背景T载体的通用方法。使用含有ccdB致死基因的gateway cassette 片段作为插入DNA片段以降低背景干扰,连接到pGEM-T easy 载体骨架上,通过内切酶XcmI酶切重组质粒即得到T 载体。对重组质粒进行了酶切,PCR 和测序验证,并且利用连接效率实验证实了T 载体具有100% 的阳性克隆率。构建的T载体不仅继承了pGEM-T easy的众多优点,而且具有高效、低背景的卓越特点;另外,引入的常用限制性内切酶和 LR重组反应介导的gateway 技术为亚克隆提供了便利。     

Simple Method for Markerless Gene Deletion in Multidrug-Resistant Acinetobacter baumannii

The traditional markerless gene deletion technique based on overlap extension PCR has been used for generating gene deletions in multidrug-resistant Acinetobacter baumannii. However, the method is time-consuming because it requires restriction digestion of the PCR products in DNA cloning and the construction of new vectors containing a suitable antibiotic resistance cassette for the selection of A. baumannii merodiploids. Moreover, the availability of restriction sites and the selection of recombinant bacteria harboring the desired chimeric plasmid are limited, making the construction of a chimeric plasmid more difficult. We describe a rapid and easy cloning method for markerless gene deletion in A. baumannii, which has no limitation in the availability of restriction sites and allows for easy selection of the clones carrying the desired chimeric plasmid. Notably, it is not necessary to construct new vectors in our method. This method utilizes direct cloning of blunt-end DNA fragments, in which upstream and downstream regions of the target gene are fused with an antibiotic resistance cassette via overlap extension PCR and are inserted into a blunt-end suicide vector developed for blunt-end cloning. Importantly, the antibiotic resistance cassette is placed outside the downstream region in order to enable easy selection of the recombinants carrying the desired plasmid, to eliminate the antibiotic resistance cassette via homologous recombination, and to avoid the necessity of constructing new vectors. This strategy was successfully applied to functional analysis of the genes associated with iron acquisition by A. baumannii ATCC 19606 and to ompA gene deletion in other A. baumannii strains. Consequently, the proposed method is invaluable for markerless gene deletion in multidrug-resistant A. baumannii.     

毛竹笋全长cDNA文库构建

Gateway技术构建cDNA文库,利用了λ噬菌体的位点特异性重组,避免使用限制性内酶切割cDNA,能够解决常规方法构建cDNA文库的技术缺陷。应用Gateway技术构建毛竹笋cDNA文库,经检测cDNA入门文库的滴度达到1.7×106cfu/mL,文库总容量为8.5×106cfu,平均插入片段在1.0 kb以上。毛竹笋文库的构建为进一步克隆毛竹纤维化分子机理打下了基础。     

A Modified MultiSite Gateway Cloning Strategy for Consolidation of Genes in Plants

The genome information is offering opportunities to manipulate genes, polygenic characters and multiple traits in plants. Although a number of approaches have been developed to manipulate traits in plants, technical hurdles make the process difficult. Gene cloning vectors that facilitate the fusion, overexpression or down regulation of genes in plant cells are being used with various degree of success. In this study, we modified gateway MultiSite cloning vectors and developed a hybrid cloning strategy which combines advantages of both traditional cloning and gateway recombination cloning. We developed Gateway entry (pGATE) vectors containing attL sites flanking multiple cloning sites and plant expression vector (pKM12GW) with specific recombination sites carrying different plant and bacterial selection markers. We constructed a plant expression vector carrying a reporter gene (GUS), two Bt cry genes in a predetermined pattern by a single round of LR recombination reaction after restriction endonuclease-mediated cloning of target genes into pGATE vectors. All the three transgenes were co-expressed in Arabidopsis as evidenced by gene expression, histochemical assay and insect bioassay. The pGATE vectors can be used as simple cloning vectors as there are rare restriction endonuclease sites inserted in the vector. The modified multisite vector system developed is ideal for stacking genes and pathway engineering in plants.     

Development of a novel Gateway-based vector system for efficient, multiparallel protein expression in Escherichia coli

We describe a cloning and expression system which is based on the Escherichia coli T7 expression system and Gateway recombination technology. We have produced numerous destination vectors with selected fusion tags and an additional set of entry vectors containing the gene of interest and optional labeling tags. This powerful system enables us to transfer a cDNA to several expression vectors in parallel and combine them with various labeling tags. To remove the attached amino terminal tags along with the unwanted attB1 site, we inserted PreScission protease cleavage sites. In contrast to the commercially available destination vectors, our plasmids provide kanamycin resistance, which can be an advantage when expressing toxic proteins in E. coli. Some small-scale protein expression experiments are shown to demonstrate the usefulness of these novel Gateway vectors. In summary, this system has some benefits over the widely used and commercially available Gateway standard system, and it enables many different combinations for expression constructs from a single gene of interest.     

Expression of rabies virus glycoprotein gene into eukaryotic system and determination of potential T-cell epitopes

The present study was undertaken to clone, express rabies virus glycoprotein (RVG) and to identify potential T-cell epitopes on it. RVG gene (1590 bp) was amplified using gene specific primers. The amplified product was cloned into pTZ57R/T cloning vector by TA cloning. RVG gene was subcloned into pcDNA3.1 (+) expression vector. In this study, cloning and expression of rabies virus glycoprotein gene was done under CMV promoter and an expression construct (pcDNA.RVG) was prepared and clones were confirmed by restriction digestion, colony PCR and nucleotide sequencing. The expression construct was further characterized by western blotting and indirect fluorescent antibody test (IFAT). In silico analysis of this protein was done to find out potential antigenic sites so that it can be further evaluated for its potential as candidate for epitope vaccine against rabies.     

An Alternative Approach in Gateway® Cloning when the Bacterial Antibiotic Selection Cassettes of the Entry Clone and Destination Vector are the Same

The Gateway^® recombination technology has revolutionized the method of gene cloning for functional analyses and high-throughput ORFeome projects. In general, Gateway cloning is highly efficient because after LR recombination and bacterial transformation, only cells containing the recombinant destination clone are selected on an antibiotic selection plate. However, when the antibiotic resistance gene for bacterial selection is the same in the entry and destination vectors, the direct selection of recombinant destination clones on an antibiotic plate is difficult. Here, we demonstrate an efficient and comprehensive approach to obtain positive destination clones directly on an antibiotic selection plate in this situation. The strategy involves polymerase chain reaction (PCR)-mediated amplification of the entry clone using entry vector-specific primers that bind outside the attL sequences and the subsequent use of this purified PCR product for LR recombination with the destination vector. Our results suggest that cloning of linear DNA fragments into circular destination vectors through LR recombination is an efficient method for inserts up to 7 kb in size. Using this approach, the yield of colony PCR positive destination clones was 100 % for genes of various sizes tested in our experiments.     

基于XcmⅠ酶切的高效TA克隆载体的构建

目的：制备基于XcmⅠ酶切的高效TA克隆载体,并检测其克隆PCR产物的效果。方法：设计一对互补配对的寡核苷酸,经过变性及退火后插入质粒pUC19的多克隆位点,从而在该多克隆位点中引入2个XcmⅠ酶切位点,用XcmⅠ酶切后即获得含有3’突出T碱基的T载体;为了提高该T载体的克隆效率,优化了2个XcmⅠ酶切位点之间的碱基数目,排除了载体自连产生白色克隆的可能性,使假阳性大大减少;此外,为了便于完全酶切与未完全酶切载体的分离,在2个XcmⅠ之间插入了一段无关DNA片段。结果：改进得到的T载体可以有效克隆PCR产物,其阳性克隆率可达95％。结论：构建了基于XcmⅠ酶切的TA克隆载体,经过改进的T载体具有很高的克隆效率。     

Phage lambda cDNA cloning vectors for subtractive hybridization, fusion-protein synthesis and Cre-loxP automatic plasmid subcloning

We describe the construction and use of two classes of cDNA cloning vectors. The first class comprises the lambda EXLX(+) and lambda EXLX(-) vectors that can be used for the expression in Escherichia coli of proteins encoded by cDNA inserts. This is achieved by the fusion of cDNA open reading frames to the T7 gene 10 promoter and protein-coding sequences. The second class, the lambda SHLX vectors, allows the generation of large amounts of single-stranded DNA or synthetic cRNA that can be used in subtractive hybridization procedures. Both classes of vectors are designed to allow directional cDNA cloning with non-enzymatic protection of internal restriction sites. In addition, they are designed to facilitate conversion from phage lambda to plasmid clones using a genetic method based on the bacteriophage P1 site-specific recombination system; we refer to this as automatic Cre-loxP plasmid subcloning. The phage lambda arms, lambda LOX, used in the construction of these vectors have unique restriction sites positioned between the two loxP sites. Insertion of a specialized plasmid between these sites will convert it into a phage lambda cDNA cloning vector with automatic plasmid subcloning capability.