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.     

A versatile ligation-independent cloning method suitable for high-throughput expression screening applications

This article describes the construction of a set of versatile expression vectors based on the In-Fusion™ cloning enzyme and their use for high-throughput cloning and expression screening. Modifications to commonly used vectors rendering them compatible with In-Fusion™ has produced a ligation-independent cloning system that is (1) insert sequence independent (2) capable of cloning large PCR fragments (3) efficient over a wide (20-fold) insert concentration range and (4) applicable to expression in multiple hosts. The system enables the precise engineering of (His₆-) tagged constructs with no undesirable vector or restriction-site-derived amino acids added to the expressed protein. The use of a multiple host-enabled vector allows rapid screening in both E. coli and eukaryotic hosts (HEK293T cells and insect cell hosts, e.g. Sf9 cells). These high-throughput screening activities have prompted the development and validation of automated protocols for transfection of mammalian cells and Ni-NTA protein purification.     

Flow-cytometric isolation of human antibodies from a nonimmune Saccharomyces cerevisiae surface display library

A nonimmune library of 10(9) human antibody scFv fragments has been cloned and expressed on the surface of yeast, and nanomolar-affinity scFvs routinely obtained by magnetic bead screening and flow-cytometric sorting. The yeast library can be amplified 10(10)-fold without measurable loss of clonal diversity, allowing its effectively indefinite expansion. The expression, stability, and antigen-binding properties of >50 isolated scFv clones were assessed directly on the yeast cell surface by immunofluorescent labeling and flow cytometry, obviating separate subcloning, expression, and purification steps and thereby expediting the isolation of novel affinity reagents. The ability to use multiplex library screening demonstrates the usefulness of this approach for high-throughput antibody isolation for proteomics applications.     

Rapid and Robust PCR-Based All-Recombinant Cloning Methodology

We report here a PCR-based cloning methodology that requires no post-PCR modifications such as restriction digestion and phosphorylation of the amplified DNA. The advantage of the present method is that it yields only recombinant clones thus eliminating the need for screening. Two DNA amplification reactions by PCR are performed wherein the first reaction amplifies the gene of interest from a source template, and the second reaction fuses it with the designed expression vector fragments. These vector fragments carry the essential elements that are required for the fusion product selection. The entire process can be completed in less than 8 hours. Furthermore, ligation of the amplified DNA by a DNA ligase is not required before transformation, although the procedure yields more number of colonies upon transformation if ligation is carried out. As a proof-of-concept, we show the cloning and expression of GFP, adh, and rho genes. Using GFP production as an example, we further demonstrate that the E. coli T7 express strain can directly be used in our methodology for the protein expression immediately after PCR. The expressed protein is without or with 6xHistidine tag at either terminus, depending upon the chosen vector fragments. We believe that our method will find tremendous use in molecular and structural biology.     

Going native: Direct high throughput screening of secreted full-length IgG antibodies against cell membrane proteins

Gel microdroplet – fluorescence activated cell sorting (GMD-FACS) is an innovative high throughput screening platform for recombinant protein libraries, and we show here that GMD-FACS can overcome many of the limitations associated with conventional screening methods for antibody libraries. For example, phage and cell surface display benefit from exceptionally high throughput, but generally require high quality, soluble antigen target and necessitate the use of anchored antibody fragments. In contrast, the GMD-FACS assay can screen for soluble, secreted, full-length IgGs at rates of several thousand clones per second, and the technique enables direct screening against membrane protein targets in their native cellular context. In proof-of-concept experiments, rare anti-EGFR antibody clones were efficiently enriched from a 10,000-fold excess of anti-CCR5 clones in just three days. Looking forward, GMD-FACS has the potential to contribute to antibody discovery and engineering for difficult targets, such as ion channels and G protein-coupled receptors.     

An Alternative Method to Facilitate cDNA Cloning for Expression Studies in Mammalian Cells by Introducing Positive Blue White Selection in Vaccinia Topoisomerase I-Mediated Recombination

One of the most basic techniques in biomedical research is cDNA cloning for expression studies in mammalian cells. Vaccinia topoisomerase I-mediated cloning (TOPO cloning by Invitrogen) allows fast and efficient recombination of PCR-amplified DNAs. Among TOPO vectors, a pcDNA3.1 directional cloning vector is particularly convenient, since it can be used for expression analysis immediately after cloning. However, I found that the cloning efficiency was reduced when RT-PCR products were used as inserts (about one-quarter). Since TOPO vectors accept any PCR products, contaminating fragments in the insert DNA create negative clones. Therefore, I designed a new mammalian expression vector enabling positive blue white selection in Vaccinia topoisomerase I–mediated cloning. The method utilized a short nontoxic LacZα peptide as a linker for GFP fusion. When cDNAs were properly inserted into the vector, minimal expression of the fusion proteins in E. coli (harboring lacZΔM15) resulted in formation of blue colonies on X-gal plates. This method improved both cloning efficiency (75%) and directional cloning (99%) by distinguishing some of the negative clones having non-cording sequences, since these inserts often disturbed translation of lacZα. Recombinant plasmids were directly applied to expression studies using GFP as a reporter. Utilization of the P2A peptide allowed for separate expression of GFP. In addition, the preparation of Vaccinia topoisomerase I-linked vectors was streamlined, which consisted of successive enzymatic reactions with a single precipitation step, completing in 3 hr. The arrangement of unique restriction sites enabled further modification of vector components for specific applications. This system provides an alternative method for cDNA cloning and expression in mammalian cells.     

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.     

Substrate-induced gene-expression screening of environmental metagenome libraries for isolation of catabolic genes

Recent awareness that most microorganisms in the environment are resistant to cultivation has prompted scientists to directly clone useful genes from environmental metagenomes. Two screening methods are currently available for the metagenome approach, namely, nucleotide sequence-based screening and enzyme activity-based screening. Here we have introduced and optimized a third option for the isolation of novel catabolic operons, that is, substrate-induced gene expression screening (SIGEX). This method is based on the knowledge that catabolic-gene expression is generally induced by relevant substrates and, in many cases, controlled by regulatory elements situated proximate to catabolic genes. For SIGEX to be high throughput, we constructed an operon-trap gfp-expression vector available for shotgun cloning that allows for the selection of positive clones in liquid cultures by fluorescence-activated cell sorting. The utility of SIGEX was demonstrated by the cloning of aromatic hydrocarbon-induced genes from a groundwater metagenome library and subsequent genome-informatics analysis.     

Total synthesis of multi-kilobase DNA sequences from oligonucleotides

A method for synthesizing DNA from 40-mer oligonucleotides, which we used to generate a 32-kb DNA fragment, is explained. DNA sequences are synthesized as approximately 500 bp fragments (synthons) in a two-step PCR reaction and cloned using ligation-independent cloning (LIC). Synthons are then assembled into longer full-length sequences in a stepwise manner. By initially synthesizing smaller fragments (synthons), the number of clones sequenced is low compared with synthesizing complete multi-kilobase DNA sequences in a single step. LIC eliminates the need for purification of fragments before cloning, making the process amenable to high-throughput operation and automation. Type IIs restriction enzymes allow seamless assembly of synthons without placing restrictions on the sequence being synthesized. Synthetic fragments are assembled in pairs to generate the final construct using vectors that allow selection of desired clones with two unique antibiotic resistance markers, and this eliminates the need for purification of fragments after digestion with restriction endonucleases.     

A series of novel directional cloning and expression vectors for blunt-end ligation of PCR products

Novel directional cloning and expression vectors were developed for blunt-end ligation of PCR products that are suitable for high-throughput cloning and simplifying the screening procedure. The PCR products, without further processing, are cloned into vectors digested with SchI and, following transformation, the desired recombinants give typical blue colonies on selectable plates. The principle of this selection strategy is that the construction also generates a full-length ideal lacO gene. To the best of our knowledge, this is the first time that this lacO reconstruction strategy has been applied in the selection of recombinants.     

A novel cloning system for direct screening using a suicidal strategy

The pAC92 plasmid is a direct screening cloning vector which allows positive selection of recombinant clones (re-clones). This new high-copy-number plasmid vector encodes ampicillin resistance and carries the Bacillus subtilis α-amylase (α-Amy)-encoding gene (amy) containing a multiple cloning site. The pAC92 plasmid confers to Escherichia coli transformants an amylolytic phenotype easily detected by iodine vapor staining. The re-clones are identified by insertional inactivation of α-Amy activity. During pAC92 construction, a bacterial growth defect was observed in host cells after some modifications of the promoter region that caused the increase in the amy expression. This suicide characteristic permitted the positive selection of re-clones. A second transformation step was performed to enhance the rate of re-clones per plate.     

Generation of full-length cDNA libraries enriched for differentially expressed genes for functional genomics

Here, we describe the application of a RecA-based cloning technology to generate full-length cDNA libraries enriched for genes that are differentially expressed between tumor and normal tissue samples. First, we show that the RecA-based method can be used to enrich cDNA libraries for several target genes in a single reaction. Then, we demonstrate that this method can be extended to enrich a cDNA library for many full-length cDNA clones using fragments derived from a subtracted cDNA population. The results of these studies show that this RecA-mediated cloning technology can be used to convert subtracted cDNAs or a mixture of several cDNA fragments corresponding to differentially expressed genes into a full-length library in a single reaction. This procedure yields a population of expression-ready clones that can be used for further high-throughput functional screening.     

Therapeutic antibody engineering by high efficiency cell screening

In recent years, several cell-based screening technologies for the isolation of antibodies with prescribed properties emerged. They rely on the multi-copy display of antibodies or antibody fragments on a cell surface in functional form followed by high through put screening and isolation of cell clones that carry an antibody variant with the desired affinity, specificity, and stability. Particularly yeast surface display in combination with high-throughput fluorescence-activated cell sorting has proven successful in the last fifteen years as a very powerful technology that has some advantages over classical generation of monoclonals using the hybridoma technology or bacteriophage-based antibody display and screening. Cell-based screening harbours the benefit of single-cell online and real-time analysis and characterisation of individual library candidates. Moreover, when using eukaryotic expression hosts, intrinsic quality control machineries for proper protein folding and stability exist that allow for co-selection of high-level expression and stability simultaneously to the binding functionality. Recently, promising technologies emerged that directly rely on antibody display on higher eukaryotic cell lines using lentiviral transfection or direct screening on B-cells. The combination of immunisation, B-cell screening and next generation sequencing may open new avenues for the isolation of therapeutic antibodies with prescribed physicochemical and functional characteristics.     

Development of a novel mammalian cell surface antibody display platform

Antibody display systems have been successfully applied to screen, select and characterize antibody fragments. These systems typically use prokaryotic organisms such as phage and bacteria or lower eukaryotic organisms, such as yeast. These organisms possess either no or different post-translational modification functions from mammalian cells and prefer to display small antibody fragments instead of full-length IgGs. We report here a novel mammalian cell-based antibody display platform that displays full-length functional antibodies on the surface of mammalian cells. Through recombinase-mediated DNA integration, each host cell contains one copy of the gene of interest in the genome. Utilizing a hot-spot integration site, the expression levels of the gene of interest are high and comparable between clones, ensuring a high signal to noise ratio. Coupled with fluorescence-activated cell sorting (FACS) technology, our platform is high throughput and can distinguish antibodies with very high antigen binding affinities directly on the cell surface. Single-round FACS can enrich high affinity antibodies by more than 500-fold. Antibodies with significantly improved neutralizing activity have been identified from a randomly mutagenized library, demonstrating the power of this platform in screening and selecting antibody therapeutics.Key words: antibody display, mammalian display, antibody library, vector, antibody screen, affinity maturation     

Development of a novel mammalian cell surface antibody display platform

Antibody display systems have been successfully applied to screen, select and characterize antibody fragments. These systems typically use prokaryotic organisms such as phage and bacteria or lower eukaryotic organisms, such as yeast. These organisms possess either no or different post-translational modification functions from mammalian cells and prefer to display small antibody fragments instead of full-length IgGs. We report here a novel mammalian cell-based antibody display platform that displays full-length functional antibodies on the surface of mammalian cells. Through recombinase-mediated DNA integration, each host cell contains one copy of the gene of interest in the genome. Utilizing a hot-spot integration site, the expression levels of the gene of interest are high and comparable between clones, ensuring a high signal to noise ratio. Coupled with fluorescence-activated cell sorting (FACS) technology, our platform is high throughput and can distinguish antibodies with very high antigen binding affinities directly on the cell surface. Single-round FACS can enrich high affinity antibodies by more than 500 fold. Antibodies with significantly improved neutralizing activity have been identified from a randomly mutagenized library, demonstrating the power of this platform in screening and selecting antibody therapeutics.     

Phenotypic Expression of PCR-Generated Random Mutations in a Pseudomonas putida Gene after Its Introduction into an Acinetobacter Chromosome by Natural Transformation

Localized sets of random point mutations generated by PCR amplification can be transferred efficiently to the chromosome of Acinetobacter ADP1 (also known as strain BD413) by natural transformation. The technique does not require cloning of PCR fragments in plasmids: PCR-amplified DNA fragments are internalized by cells and directly incorporated into their genomes by homologous recombination. Previously such procedures for random mutagenesis could be applied only to Acinetobacter genes affording the selection of mutant phenotypes. Here we describe the construction of a vector and recipient that allow for mutagenesis, recovery, and expression of heterologous genes that may lack a positive selection. The plasmid carries an Acinetobacter chromosomal segment interrupted by a multiple cloning site next to a kanamycin resistance marker. The insertion of heterologous DNA into the multiple cloning site prepares the insert as a target for PCR mutagenesis. PCR amplifies the kanamycin resistance marker and a flanking region of Acinetobacter DNA along with the insert of heterologous DNA. Nucleotide sequence identity between the flanking regions and corresponding chromosomal segments in an engineered Acinetobacter recipient allows homologous recombination of the PCR-amplified DNA fragments into a specific chromosomal docking site from which they can be expressed. The recipient strain contains only a portion of the kanamycin resistance gene, so donor DNA containing both this gene and the mutagenized insert can be selected by demanding growth of recombinants in the presence of kanamycin. The effectiveness of the technique was demonstrated with the relatively GC-rich Pseudomonas putida xylE gene. After only one round of PCR amplification (35 cycles), donor DNA produced transformants of which up to 30% carried a defective xylE gene after growth at 37°C. Of recombinant clones that failed to express xylE at 37°C, about 10% expressed the gene when grown at 22°C. The techniques described here could be adapted to prepare colonies with an altered function in any gene for which either a selection or a suitable phenotypic screen exists.     

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.     

Tapping diversity lost in transformations—in vitro amplification of ligation reactions

Molecular evolution is a powerful means of engineering proteins. It usually requires the generation of a large recombinant DNA library of variants for cloning into a phage or plasmid vector, and the transformation of a host organism for expression and screening of the variant proteins. However, library size is often limited by the low yields of circular DNA and the poor transformation efficiencies of linear DNA. Here we have overcome this limitation by amplification of recombinant circular DNA molecules directly from ligation reactions. The amplification by bacteriophage Phi29 polymerase increased the number of transformants; thus from a nanogram-scale ligation of DNA fragments comprising two sub-libraries of variant antibody domains, we succeeded in amplifying a highly diverse and large combinatorial phage antibody library (>10⁹ transformants in Escherichia coli and 10⁵-fold more transformants than without amplification). From the amplified library, but not from the smaller un-amplified library, we could isolate several antibody fragments against a target antigen. It appears that amplification of ligations with Phi29 polymerase can help recover clones and molecular diversity otherwise lost in the transformation step. A further feature of the method is the option of using PCR-amplified vectors for ligations.     

A genetic system for direct selection of gene-positive clones during recombinational cloning in yeast

Transformation-associated recombination (TAR) is a cloning technique that allows specific chromosomal regions or genes to be isolated directly from genomic DNA without prior construction of a genomic library. This technique involves homologous recombination during spheroplast transformation between genomic DNA and a TAR vector that has 5′ and 3′ gene targeting sequences (hooks). Typically, TAR cloning produces positive YAC recombinants at a frequency of ~0.5%; the positive clones are identified by PCR or colony hybridization. This paper describes a novel TAR cloning procedure that selects positive clones by positive and negative genetic selection. This system utilizes a TAR vector with two targeting hooks, HIS3 as a positive selectable marker, URA3 as a negative selectable marker and a gene-specific sequence called a loop sequence. The loop sequence lies distal to a targeting hook sequence in the chromosomal target, but proximal to the targeting hook and URA3 in the TAR vector. When this vector recombines with chromosomal DNA at the gene-specific targeting hook, the recombinant YAC product carries two copies of the loop sequence, therefore, the URA3 negative selectable marker becomes mitotically unstable and is lost at high frequency by direct repeat recombination involving the loop sequence. Positive clones are identified by selecting against URA3. This method produces positive YAC recombinants at a frequency of ~40%. This novel TAR cloning method provides a powerful tool for structural and functional analysis of complex genomes.     

High-throughput retrieval of physical DNA for NGS-identifiable clones in phage display library

In antibody discovery, in-depth analysis of an antibody library and high-throughput retrieval of clones in the library are crucial to identifying and exploiting rare clones with different properties. However, existing methods have technical limitations, such as low process throughput from the laborious cloning process and waste of the phenotypic screening capacity from unnecessary repetitive tests on the dominant clones. To overcome the limitations, we developed a new high-throughput platform for the identification and retrieval of clones in the library, TrueRepertoire?. This new platform provides highly accurate sequences of the clones with linkage information between heavy and light chains of the antibody fragment. Additionally, the physical DNA of clones can be retrieved in high throughput based on the sequence information. We validated the high accuracy of the sequences and demonstrated that there is no platform-specific bias. Moreover, the applicability of TrueRepertoire? was demonstrated by a phage-displayed single-chain variable fragment library targeting human hepatocyte growth factor protein.