A Series of TA-Based and Zero-Background Vectors for Plant Functional Genomics

With the sequencing of genomes from many organisms now complete and the development of high-throughput sequencing, life science research has entered the functional post-genome era. Therefore, deciphering the function of genes and how they interact is in greater demand. To study an unknown gene, the basic methods are either overexpression or gene knockout by creating transgenic plants, and gene construction is usually the first step. Although traditional cloning techniques using restriction enzymes or a site-specific recombination system (Gateway or Clontech cloning technology) are highly useful for efficiently transferring DNA fragments into destination plasmids, the process is time consuming and expensive. To facilitate the procedure of gene construction, we designed a TA-based cloning system in which only one step was needed to subclone a DNA fragment into vectors. Such a cloning system was developed from the pGreen binary vector, which has a minimal size and facilitates construction manipulation, combined with the negative selection marker gene ccdB, which has the advantages of eliminating the self-ligation background and directly enabling high-efficiency TA cloning technology. We previously developed a set of transient and stable transformation vectors for constitutive gene expression, gene silencing, protein tagging, subcellular localization analysis and promoter activity detection. Our results show that such a system is highly efficient and serves as a high-throughput platform for transient or stable transformation in plants for functional genome research.     

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.     

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。     

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.     

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。     

Ribosomal Binding Site Switching: An Effective Strategy for High-Throughput Cloning Constructions

Direct cloning of PCR fragments by TA cloning or blunt end ligation are two simple methods which would greatly benefit high-throughput (HTP) cloning constructions if the efficiency can be improved. In this study, we have developed a ribosomal binding site (RBS) switching strategy for direct cloning of PCR fragments. RBS is an A/G rich region upstream of the translational start codon and is essential for gene expression. Change from A/G to T/C in the RBS blocks its activity and thereby abolishes gene expression. Based on this property, we introduced an inactive RBS upstream of a selectable marker gene, and designed a fragment insertion site within this inactive RBS. Forward and reverse insertions of specifically tailed fragments will respectively form an active and inactive RBS, thus all background from vector self-ligation and fragment reverse insertions will be eliminated due to the non-expression of the marker gene. The effectiveness of our strategy for TA cloning and blunt end ligation are confirmed. Application of this strategy to gene over-expression, a bacterial two-hybrid system, a bacterial one-hybrid system, and promoter bank construction are also verified. The advantages of this simple procedure, together with its low cost and high efficiency, makes our strategy extremely useful in HTP cloning constructions.     

An advanced blue-white screening method for construction of shRNA expression vectors

Short hairpin RNA (shRNA) encoded within an expression vector is an effective tool for exploration of gene function in mammalian cells. Many of the current methods for constructing shRNA expression vectors require cumbersome and time-consuming procedures for identification of the desired recombinants. We have developed a highly efficient and less labor-intensive cloning method that allows the construction of shRNA expression vectors in one day and with minimal effort. This advanced blue-white screening technique was developed by combining the reconstitution of ideal lacO with TA cloning. The DNAs are simply ligated into the destination vectors and, following transformation, a desired recombinant event will give a typical blue colony. In addition, we have used this cloning method for the construction of targeting reporter expression vectors to measure the efficacy of the corresponding shRNA. We constructed 122 functional shRNA expression vectors and sequencing of the positive cloning vectors confirmed a high degree of accuracy. Only three short DNA primers are needed for constructing both shRNA and targeting reporter expression vectors. This advanced blue-white screening system is a powerful tool for the high-throughput assay of RNAi libraries.     

Efficient and high-throughput vector construction and Agrobacterium-mediated transformation of Arabidopsis thaliana suspension-cultured cells for functional genomics

We established a large-scale, high-throughput protocol to construct Arabidopsis thaliana suspension-cultured cell lines, each of which carries a single transgene, using Agrobacterium-mediated transformation. We took advantage of RIKEN Arabidopsis full-length (RAFL) cDNA clones and the Gateway cloning system for high-throughput preparation of binary vectors carrying individual full-length cDNA sequences. Throughout all cloning steps, multiple-well plates were used to treat 96 samples simultaneously in a high-throughput manner. The optimal conditions for Agrobacterium-mediated transformation of 96 independent binary vector constructs were established to obtain transgenic cell lines efficiently. We evaluated the protocol by generating transgenic Arabidopsis T87 cell lines carrying individual 96 metabolism-related RAFL cDNA fragments, and showed that the protocol was useful for high-throughput and large-scale production of gain-of-function lines for functional genomics.     

IRDL Cloning: A One-Tube,Zero-Background,Easy-to-Use,Directional Cloning Method Improves Throughput in Recombinant DNA Preparation

Rapid and efficient construction of expression vectors and subsequent transformation are basic recombinant methods for the investigation of gene functionality. Although novel cloning methods have recently been developed, many laboratories worldwide continue to use traditional restriction digestion-ligation methods to construct expression vectors owing to financial constraints and the unavailability of appropriate vectors. We describe an improved restriction digestion-ligation (IRDL) cloning method that combines the advantage of directional cloning from double digestion-ligation with that of a low background observed by using a positive selection marker gene ccdB to facilitate digestion and ligation in a single tube. The IRDL cloning overcomes the time-consuming and laborious limits of traditional methods, thereby providing an easy-to-use, low-cost, and one-step strategy for directional cloning of target DNA fragments into an expression vector. As a proof-of-concept example, we developed two yeast vectors to demonstrate the feasibility and the flexibility of the IRDL cloning method. This method would provide an effective and easy-to-use system for gene cloning and functional genomics studies.     

Using a modified TA cloning method to create entry clones

We describe a noncommercial alternative method to create entry clones compatible with all kinds of destination vectors based on an improved TA cloning approach. To generate Gateway T vectors, we first constructed gentamicin- and chloramphenicol-resistant entry vectors designated pGWG and pGWC, respectively. Each entry vector contains an AhdI cassette flanked by attL sites, with each AhdI cassette containing two AhdI restriction enzyme sites spaced by the ccdB killer gene, which is lethal to most Escherichia coli strains. Gateway T vectors can be prepared by simple digestion of these entry vectors with the AhdI enzyme or its isoschizomers. The use of the ccdB gene as a negative selection marker is an important improvement over conventional TA cloning in that it eliminates the necessity of blue/white color screening based on alpha-complementation. Another important improvement that we have implemented is to retail the T vectors using Taq polymerase and dTTP so as to improve the cloning efficiency. Together, these improvements allow TA cloning to realize its full potential. Using Gateway T vectors prepared by this improved method, entry clones for PCR products or restriction enzyme fragments can be created simply, efficiently, and inexpensively while at the same time introducing greater compatibility.     

Construction and evaluation of multisite recombinatorial (Gateway) cloning vectors for Gram-positive bacteria

Background  

The Gateway recombinatorial cloning system allows easy and rapid joining of DNA fragments. Here we report the construction and evaluation of three different Gram-positive vectors that can be used with the Multisite Gateway cloning system to rapidly produce new gene arrangements in plasmid constructs for use in a variety of Gram-positive bacteria.     

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.     

几种新型植物基因表达载体的构建方法

利用基因工程技术手段研究基因功能过程中,构建基因表达载体处于转基因植物的主导地位,采用合适的构建方法会使实验效果事半功倍。植物基因表达载体的构建方法除了传统构建法、Gateway技术、三段T-DNA法、一步克隆法等,还有近年来出现的几种新型的载体构建方法:基于竞争性连接原理快速构建小片段基因表达载体;MicroRNA前体PCR置换法适用于构建小分子RNA表达载体;重组融合PCR法特别适用于插入片段中含有较多限制性酶切位点的载体构建;利用In-Fusion试剂盒可以将任何目的片段插入一个线性化载体的某个区域;构建多片段复杂载体可采用不依赖序列和连接的克隆方法(Sequence and ligation-independent cloning,SLIC)法;Gibson等温拼接法;Golden Gate拼接法。本文将在总结分析前人工作的基础上,结合自己工作的体会和经验分析这7种新方法的特点,期望通过这几种新的方法给植物基因工程表达载体的构建提供新的思路。     

用于通路(Gateway)克隆技术的植物表达载体研究进展

通路(Gateway)克隆技术是根据λ噬菌体基因组和大肠杆菌基因组之间的位点专一性重组分子机制开发的一套分子克隆新技术.利用该技术LR反应构建目的基因的表达载体时不需要经过酶切和连接等繁琐而又费时的过程,因此,可以节省很多时间.为了扩大Gateway技术在植物基因工程领域的应用,最近有很多研究机构和研究小组开发了能用于组成型或诱导型表达目的基因、基因沉默、启动子分析、蛋白质亚细胞定位、蛋白质/蛋白质相互作用、多个DNA片段的模块化组装和DNA组片段功能验证等研究用的植物表达载体.该文对这些技术的研究进展进行了综述.     

Gateway-compatible vectors for plant functional genomics and proteomics

Gateway cloning technology facilitates high-throughput cloning of target sequences by making use of the bacteriophage lambda site-specific recombination system. Target sequences are first captured in a commercially available "entry vector" and are then recombined into various "destination vectors" for expression in different experimental organisms. Gateway technology has been embraced by a number of plant laboratories that have engineered destination vectors for promoter specificity analyses, protein localization studies, protein/protein interaction studies, constitutive or inducible protein expression studies, gene knockdown by RNA interference, or affinity purification experiments. We review the various types of Gateway destination vectors that are currently available to the plant research community and provide links and references to enable additional information to be obtained concerning these vectors. We also describe a set of "pEarleyGate" plasmid vectors for Agrobacterium-mediated plant transformation that translationally fuse FLAG, HA, cMyc, AcV5 or tandem affinity purification epitope tags onto target proteins, with or without an adjacent fluorescent protein. The oligopeptide epitope tags allow the affinity purification, immunolocalization or immunoprecipitation of recombinant proteins expressed in vivo. We demonstrate the utility of pEarleyGate destination vectors for the expression of epitope-tagged proteins that can be affinity captured or localized by immunofluorescence microscopy. Antibodies detecting the FLAG, HA, cMyc and AcV5 tags show relatively little cross-reaction with endogenous proteins in a variety of monocotyledonous and dicotyledonous plants, suggesting broad utility for the tags and vectors.     

Retroviral vectors for homologous recombination provide efficient cloning and expression in mammalian cells

Homologous recombination technologies enable high-throughput cloning and the seamless insertion of any DNA fragment into expression vectors. Additionally, retroviral vectors offer a fast and efficient method for transducing and expressing genes in mammalian cells, including lymphocytes. However, homologous recombination cannot be used to insert DNA fragments into retroviral vectors; retroviral vectors contain two homologous regions, the 5′- and 3′-long terminal repeats, between which homologous recombination occurs preferentially. In this study, we have modified a retroviral vector to enable the cloning of DNA fragments through homologous recombination. To this end, we inserted a bacterial selection marker in a region adjacent to the gene insertion site. We used the modified retroviral vector and homologous recombination to clone T-cell receptors (TCRs) from single Epstein Barr virus-specific human T cells in a high-throughput and comprehensive manner and to efficiently evaluate their function by transducing the TCRs into a murine T-cell line through retroviral infection. In conclusion, the modified retroviral vectors, in combination with the homologous recombination method, are powerful tools for the high-throughput cloning of cDNAs and their efficient functional analysis.     

单子叶植物RNA干扰和过表达Gateway载体的构建

基因枪和农杆菌介导的遗传转化是目前常用的两种单子叶植物遗传转化方法。载体的发展和改良是提高植物遗传转化效率的重要基础,RNA干扰载体和过表达载体是目前通过遗传转化研究植物基因功能的主要工具。Gateway克隆技术是一种基于lambda噬菌体特异位点重组特性的通用克隆技术,该技术可以将大批目的基因方便、快捷地连接到受体载体上。本文利用Gateway技术结合传统酶切、连接方法,构建了适用于单子叶植物基因枪和农杆菌转化的RNA干扰Gateway载体pAHC-PSK-RNAi、pClean-G185-RNAi和过表达Gateway载体pAHC-PSK-OE和pClean-G185-OE,为利用基因枪和农杆菌介导的遗传转化,在小麦和水稻等单子叶植物中进行规模化基因功能研究奠定了基础。     

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).     

Construction of two Gateway vectors for gene expression in fungi

We report the construction of two Gateway fungal expression vectors pCBGW and pGWBF. The pCBGW was generated by introducing an expression cassette, which consists of a Gateway recombinant cassette (attR1-Cmr-ccdB-attR2) under the control of fungal promoter PgpdA and a terminator TtrpC, into the multiple cloning site of fungal vector pCB1004. The pGWBF is a binary vector, which was generated from the plant expression vector pGWB2 by replacing the CaMV35S promoter with PgpdA. The pGWBF can be transformed into fungi efficiently with Agrobacterium-mediated transformation. The applicability of two newly constructed vectors was tested by generating the destination vectors pGWBF-GFP and pCBGW-GFP and examining the expression of GFP gene in Trichoderma viride and Gibberella fujikuroi, respectively. Combining with the advantage of Gateway cloning technology, pCBGW and pGWBF will be useful in fungi for large-scale investigation of gene functions by constructing the interested gene destination/expression vectors in a high-throughput way.     

Building blocks for plant gene assembly

The MultiSite Gateway cloning system, based on site-specific recombination, enables the assembly of multiple DNA fragments in predefined order, orientation, and frame register. To streamline the construction of recombinant genes for functional analysis in plants, we have built a collection of 36 reference Gateway entry clones carrying promoters, terminators, and reporter genes, as well as elements of the LhG4/LhGR two-component system. This collection obeys simple engineering rules. The genetic elements (parts) are designed in a standard format. They are interchangeable, fully documented, and can be combined at will according to the desired output. We also took advantage of the MultiSite Gateway recombination sites to create vectors in which two or three genes can be cloned simultaneously in separate expression cassettes. To illustrate the flexibility of these core resources for the construction of a wide variety of plant transformation vectors, we generated various transgenes encoding fluorescent proteins and tested their activity in plant cells. The structure and sequence of all described plasmids are accessible online at http://www.psb.ugent.be/gateway/. All accessions can be requested via the same Web site.