Fast and efficient generation of recombinant baculoviruses by in vitro transposition

A novel recombinant bacmid, bEasyBac, that enables the easy and fast generation of pure recombinant baculovirus without any purification step was constructed. In bEasyBac, attR recombination sites were introduced to facilitate the generation of a recombinant viral genome by in vitro transposition. Moreover, the extracellular RNase gene from Bacillus amyloliquefaciens, barnase, was expressed under the control of the Cotesia plutellae bracovirus early promoter to negatively select against the non-recombinant background. The bEasyBac bacmid could only replicate in host insect cells when the barnase gene was replaced with the gene of interest by in vitro transposition. When bEasyBac was transposed with pDualBac-EGFP, the resulting recombinant virus, AcEasy-EGFP, showed comparable levels of EGFP expression efficiency to the plaque-purified recombinant virus AcEGFP, which was constructed using the bAcGOZA system. In addition, no non-recombinant backgrounds were detected in unpurified AcEasy-EGFP stocks. Based on these results, a high-throughput system for the generation of multiple recombinant viruses at a time was established.     

Transfection techniques for producing recombinant baculoviruses

The production of recombinant baculoviruses usually employs cotransfection of insect tissue-culture cells with viral and transfer-plasmid DNAs. The preparation and storage of viral and plasmid DNAs suitable for optimal transfection of insect cells are discussed. Electroporation, calcium-phosphate, and lipofection transfection techniques are presented with a discussion of their relative advantages. The rates of recombinant virus formation are compared using viral infection/plasmid transfection protocols versus contransfection of cells with transfer-plasmid and viral DNAs.     

A new, rapid and simple procedure for direct cloning of PCR products into baculoviruses.

We propose a novel method for direct cloning of foreign genes into baculoviruses which avoids the use of bacterial transfer vectors. The foreign gene to be inserted is derived by PCR using appropriate primers each of which contains an additional 50 nt of baculovirus sequence for homologous recombination between the PCR-derived DNA and the baculovirus DNA, thus accomplishing insertion of the foreign gene into the baculovirus. The direct cloning of green fluorescent protein and beta-glucuronidase in different baculovirus loci is described. The method is simple and avoids the use of cumbersome techniques associated with enzymatic treatment and DNA purification.     

An efficient strategy for high-throughput expression screening of recombinant integral membrane proteins

The recombinant expression of integral membrane proteins is considered a major challenge, and together with the crystallization step, the major hurdle toward routine structure determination of membrane proteins. Basic methodologies for high-throughput (HTP) expression optimization of soluble proteins have recently emerged, providing statistically significant success rates for producing such proteins. Experimental procedures for handling integral membrane proteins are generally more challenging, and there have been no previous comprehensive reports of HTP technology for membrane protein production. Here, we present a generic and integrated parallel HTP strategy for cloning and expression screening of membrane proteins in their detergent solubilized form. Based on this strategy, we provide overall success rates for membrane protein production in Escherichia coli, as well as initial benchmarking statistics of parameters such as expression vectors, strains, and solubilizing detergents. The technologies were applied to 49 E. coli integral membrane proteins with human homologs and revealed that 71% of these proteins could be produced at sufficient levels to allow milligram amounts of protein to be relatively easily purified, which is a significantly higher success rate than anticipated. We attribute the high success rate to the quality and robustness of the methodology used, and to introducing multiple parameters such as different vectors, strains, and detergents. The presented strategy demonstrates the usefulness of HTP technologies for membrane protein production, and the feasibility of large-scale programs for elucidation of structure and function of bacterial integral membrane proteins.     

Highly efficient generation of recombinant baculoviruses by enzymatically medicated site-specific in vitro recombination.

We have used the Cre-lox system of bacteriophage P1 to develop a highly efficient in vitrosystem for construction of recombinant baculoviruses. A positive visual selection has been included to make identification of recombinant viral progeny rapid and straightforward. We report recombination frequencies as high as 5 x 10(7) recombinants/micrograms starting plasmid DNA and under certain conditions, up to 50% of the viral progeny are recombinants. Genes inserted into the baculovirus genome can be readily recovered in a simple one step process and re-inserted after manipulation if required. We have confirmed the structure of recovered plasmids by diagnostic restriction endonuclease digestion and the structure of recombinant viral genomes by Southern analysis. Possible uses and the significance of the system are discussed and experiments currently being done to improve it are described.     

Development of a high-throughput cloning strategy for characterization of Acinetobacter baumannii drug transporter proteins

Heterologous expression of membrane proteins in Escherichia coli often requires optimization to overcome problems with toxicity of the recombinant protein to the host cell. A number of Gateway-based destination vectors were constructed to investigate expression of membrane proteins using a high-throughput approach. These vectors were tested using putative drug transporter proteins from the multidrug and toxic compound extrusion (MATE) family and the resistance-nodulation-cell division superfamily encoded by the human pathogen Acinetobacter baumannii. Active transport of antibiotics and antiseptics mediated by efflux proteins contributes to the high level of multidrug resistance observed in A. baumannii. Substrates for 4 of the 5 putative efflux proteins investigated were identified using the expression vectors designed in this study. Additionally, a Gateway-based suicide vector was designed for construction of specific A. baumannii insertion disruption mutants. This knockout cloning strategy was tested and shown to be successful in inactivating AbeM4, a putative MATE family protein. Therefore, we have shown that the Gateway-based vectors constructed in this study are versatile tools that can be used for manipulation and characterization of membrane proteins.     

Target-selective homologous recombination cloning for high-throughput generation of monoclonal antibodies from single plasma cells

Background  

Molecular cloning of functional immunoglobulin genes from single plasma cells is one of the most promising technologies for the rapid development of monoclonal antibody drugs. However, the proper insertion of PCR-amplified immunoglobulin genes into expression vectors remains an obstacle to the high-throughput production of recombinant monoclonal antibodies.     

Novel strategy for generation and titration of recombinant adeno-associated virus vectors

Recombinant adeno-associated virus (rAAV) vectors have many advantages for gene therapeutic applications compared with other vector systems. Several methods that use plasmids or helper viruses have been reported for the generation of rAAV vectors. Unfortunately, the preparation of large-scale rAAV stocks is labor-intensive. Moreover, the biological titration of rAAV is still difficult, which may limit its preclinical and clinical applications. For this study, we developed a novel strategy to generate and biologically titrate rAAV vectors. A recombinant pseudorabies virus (PrV) with defects in its gD, gE, and thymidine kinase genes was engineered to express the AAV rep and cap genes, yielding PS virus, which served as a packaging and helper virus for the generation of rAAV vectors. PS virus was useful not only for generating high-titer rAAV vectors by cotransfection with an rAAV vector plasmid, but also for amplifying rAAV stocks. Notably, the biological titration of rAAV vectors was also feasible when cells were coinfected with rAAV and PS virus. Based on this strategy, we produced an rAAV that expresses prothymosin alpha (ProT). Expression of the ProT protein in vitro and in vivo mediated by rAAV/ProT gene transfer was detected by immunohistochemistry and a bioassay. Taken together, our results demonstrate that the PrV vector-based system is useful for generating rAAV vectors carrying various transgenes.     

A novel high-throughput (HTP) cloning strategy for site-directed designed chimeragenesis and mutation using the Gateway cloning system

There is an increasing demand for easy, high-throughput (HTP) methods for protein engineering to support advances in the development of structural biology, bioinformatics and drug design. Here, we describe an N- and C-terminal cloning method utilizing Gateway cloning technology that we have adopted for chimeric and mutant genes production as well as domain shuffling. This method involves only three steps: PCR, in vitro recombination and transformation. All three processes consist of simple handling, mixing and incubation steps. We have characterized this novel HTP method on 96 targets with >90% success. Here, we also discuss an N- and C-terminal cloning method for domain shuffling and a combination of mutation and chimeragenesis with two types of plasmid vectors.     

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.     

A novel host-vector system for direct selection of recombinant baculoviruses (bacmids) in Escherichia coli

Site-specific transposition in Escherichia coli was used to introduce foreign genes into the Autographica californica nuclear polyhedrosis baculovirus genome. Using a temperature-sensitive donor plasmid and an E. coli host strain with an occupied Tn7 attachment site it was possible to select directly for ‘bacmid’ recombinants at 44°C. A blue to white color screen provided further confirmation of insertion at the correct site in the baculovirus genome. After cloning the gene of interest into a donor plasmid, a single transformation and plating on selective medium resulted in homogeneous baculovirus DNA which could immediately be transfected into insect cells. The utility of the host-vector system for expression in insect cells was illustrated using three heterologous genes encoding β-glucuronidase, human N-myristoyl transferase and murine preproguanylin. Using this approach, bacmid recombinants could be produced at a frequency of 10⁵ per pg input DNA. This system should not only greatly enhance the ability to obtain recombinant viruses for heterologous protein production, but should also be useful for protein engineering applications and expression cloning in insect cells.     

A plasmid cloning vector for the direct selection of strains carrying recombinant plasmids

A plasmid cloning vector with ampicillin-resistance and streptomycin-sensitivity markers is suitable for the direct selection of strains carrying recombinant plasmids. The selection for plasmid transformants utilizes their ampicillin resistance whereas selection for recombinant plasmids is based on the inactivation of the rpsL gene contained on the plasmid. When streptomycin-resistant Escherichia coli strains are used as recipients in transformation, transformants carrying the parental plasmid are phenotypically sensitive to streptomycin while those carrying hybrid plasmids are resistant to streptomycin.     

Plasmodium falciparum: recombinant baculoviruses direct the expression of circumsporozoite proteins in Spodoptera frugiperda cell cultures

The DNA coding for the circumsporozoite protein (CPS) of Plasmodium falciparum has been cloned into the baculovirus expression vector pAcYM1 and expressed in Spodoptera frugiperda (Sf9) insect cells. Three DNA constructs have been made: the first one directs the synthesis of the complete CSP (aa 1–412), the second leads to the production of a species devoid of the anchor domain (aa 1–391) and the third one to a molecule lacking both signal and membrane anchor sequences (aa 18–391). All three recombinant CPS were produced at about 3 g per 10⁶ infected cells and were characterized in terms of immunoreactivity and apparent molecular weight. Analytical purification of the recombinant proteins was achieved by a combination of heat treatment, acidification, isoelectric focusing and ion exchange chromatography. The purified material, when injected into mice, generated only modest antibody responses, although antisera from immunized mice reacted with control CSP antigens carrying or not the major immunodominant repeat region.Abbreviations AcNPV Autographa californica nuclear polyhedrosis virus - CSP circumsporozoite protein     

Circular polymerase extension cloning for high-throughput cloning of complex and combinatorial DNA libraries

High-throughput genomics, proteomics and synthetic biology studies require ever more efficient and economical strategies to clone complex DNA libraries or variants of biological modules. In this paper, we provide a protocol for a sequence-independent approach for cloning complex individual or combinatorial DNA libraries, and routine or high-throughput cloning of single or multiple DNA fragments. The strategy, called circular polymerase extension cloning (CPEC), is based on polymerase overlap extension and is therefore free of restriction digestion, ligation or single-stranded homologous recombination. CPEC is highly efficient, accurate and user friendly. Once the inserts and the linear vector have been prepared, the CPEC reaction can be completed in 10 min to 3 h, depending on the complexity of the gene libraries.     

Construction and properties of a new cloning vehicle, allowing direct sereening for recombinant plasmids

Summary pUR2, a certified B2(EK2) vector, allows easy isolation of variants containing cloned EcoRI-fragments. Bacteria harboring plasmids without inserts make blue colonies on indicator-plates, whilst those harboring recombinant plasmids make white colonies.     

Express primer tool for high-throughput gene cloning and expression

High-throughput approaches for gene cloning and expression require the development of new nonstandard tools for molecular biologists and biochemists. We introduce a Web-based tool to design primers specifically for the generation of expression clones for both laboratory-scale and high-throughput projects. The application is designed not only to allow the user complete flexibility to specify primer design parameters but also to minimize the amount of manual intervention needed to generate a large number of primers for the simultaneous amplification of multiple target genes.     

A new recombinant DNA strategy for the molecular cloning of rare membrane proteins.

We have constructed a cDNA library in the plasmid expression vector pUEX enriched in sequences encoding membrane proteins. The procedure involved positive selection of sequences common to two different rat tissues (thus excluding tissue-specific mRNA) followed by positive selection between this material and RNA extracted from membrane bound polysomes (thus excluding cytoplasmic proteins). The resultant library prepared from rat kidney cDNA hybridized with rat liver poly(A)+ RNA, contained 30,000 clones and was shown to be enriched in cDNAs encoding membrane proteins. Seventeen clones selected because they encode large fusion proteins were shown to be single copy in the library, and not present in nucleotide data banks. Thus the strategy is particularly suitable for cloning low abundance cDNAs encoding membrane proteins.     

A direct selection strategy for shotgun cloning and sequencing in the bacteriophage M13.

A new cloning strategy is described which utilizes direct selection of recombinants for shotgun sequencing in the filamentous bacteriophage M13. Direct selection is accomplished by insertional inactivation of the M13 gene X protein, a powerful inhibitor of phage-specific DNA synthesis when overproduced. An extra copy of gene X was inserted into the intergenic region of M13 and placed under the control of the bacteriophage T7 gene 10 promoter and RBS. Random fragments are cloned into the EcoRV cloning site of the new gene X cistron and recombinants are selected in an E. coli male strain producing T7 RNA polymerase. Cloning efficiencies obtained with M13-100 or phosphatase-treated M13mp19 vector are comparable. The direct selection capability of M13-100 was demonstrated to have the following advantages: (a) consistently achieved high ratios of recombinants to religated vector in the libraries, averaging about 500:1 (0.2% background), and (b) the elimination of the need for phosphatase treatment of the vector to reduce background. The direct selection strategy significantly improves the efficiency of shotgun library construction in M13, and should therefore facilitate the cloning aspects of large scale sequencing projects.