Updated Overview of TALEN Construction Systems

Transcription activator-like effector (TALE) nuclease (TALEN) is the second-generation genome editing tool consisting of TALE protein containing customizable DNA-binding repeats and nuclease domain of FokI enzyme. Each DNA-binding repeat recognizes one base of double-strand DNA, and functional TALEN can be created by a simple modular assembly of these repeats. To easily and efficiently assemble the highly repetitive DNA-binding repeat arrays, various construction systems such as Golden Gate assembly, serial ligation, and ligation-independent cloning have been reported. In this chapter, we summarize the updated situation of these systems and publicly available reagents and protocols, enabling optimal selection of best suited systems for every researcher who wants to utilize TALENs in various research fields.

High-Throughput IgG Reformatting and Expression Using Hybrid Secretion Signals and InTag Positive Selection Technology

We have previously published protocols for high-throughput IgG reformatting and expression, that enable rapid reformatting of phage-displayed antibody Fab fragments into a single dual expression vector for full IgG expression in Expi293F cells (Chen et al. Nucleic Acids Res 42:e26, 2014; Chen et al. Methods in Molecular Biology, vol 1701, 2018). However, when working with phage clones from a naïve library containing highly diverse N-terminal sequences, where the 5' PCR primers bind, the PCR step can become cumbersome. To overcome this limitation, we have investigated and found that the C-terminal 7 amino acid residues of the human antibody VH1 secretion signal can be replaced with those from ompA or pelB bacterial signals to form hybrid signal sequences that can drive strong IgG expression in Expi293F cells. The use of such hybrid signals allows any Fab fragment in the library to be amplified and cloned into the IgG expression vector using only a single 5' PCR primer targeting the bacterial secretion signal of the light or heavy chain, thus dramatically simplifying the IgG reformatting workflow.

Nicotinamide phosphoribosyltransferase purification using SUMO expression system

Nicotinamide phosphoribosyltransferase (NAMPT) is a rate-limiting enzyme in the salvage pathway required for nicotinamide adenine dinucleotide synthesis. The secreted NAMPT protein serves as a master regulatory cytokine involved in activation of evolutionarily conserved inflammatory networks. Appreciation of the role of NAMPT as a damage-associated molecular pattern protein (DAMP) has linked its activities to several disorders via Toll-like receptor 4 (TLR4) binding and inflammatory cascade activation. Information is currently lacking concerning the precise mode of the NAMPT protein functionality due to limited availability of purified protein for use in in vitro and in vivo studies. Here we report successful NAMPT expression using the pET-SUMO expression vector in E. coli strain SHuffle containing a hexa-His tag for purification. The Ulp1 protease was used to cleave the SUMO and hexa-His tags, and the protein was purified by immobilized-metal affinity chromatography. The protein yield was ~4 mg/L and initial biophysical characterization of the protein using circular dichroism revealed the secondary structural elements, while dynamic light scattering demonstrated the presence of oligomeric units. The NAMPT-SUMO showed a predominantly dimeric protein with functional enzymatic activity. Finally, we report NAMPT solubilization in n-dodecyl-β-d-maltopyranoside (DDM) detergent in monomeric form, thus enhancing the opportunity for further structural and functional investigations.

Overview of High-Throughput Cloning Methods for the Post-genomic Era

The advent of new DNA sequencing technologies leads to a dramatic increase in the number of available genome sequences and therefore of target genes with potential for functional analysis. The insertion of these sequences into proper expression vectors requires a simple an efficient cloning method. In addition, when expressing a target protein, quite often it is necessary to evaluate different DNA constructs to achieve a soluble and homogeneous expression of the target with satisfactory yields. The development of new molecular methods made possible the cloning of a huge number of DNA sequences in a high-throughput manner, necessary for meeting the increasing demands for soluble protein expression and characterization. In this chapter several molecular methods suitable for high-throughput cloning are reviewed.

A universal mini-vector and an annealing of PCR products (APP)-based cloning strategy for convenient molecular biological manipulations

Currently, the most widely used strategies for molecular cloning are sticky-end ligation-based cloning, TA cloning, blunt-end ligation-based cloning and ligase-independent cloning. In this study we have developed a novel mini-vector pANY1 which can simultaneously meet the requirements of all these cloning strategies. In addition, the selection of appropriate restriction digestion sites is difficult in some cases because of the presence of internal sites. In this study, an annealing of PCR products (APP)-based sticky-end cloning strategy was introduced to avoid this issue. Additionally, false positives occur during molecular cloning, which increases the workload of isolating positive clones. The plasmid pANY1 contains a ccdB cassette between multiple cloning sites, which efficiently avoids these false positives. Therefore, this mini-vector should serve as a useful tool with wide applications in biosciences, agriculture, food technologies, etc.

Cloning, expression and purification of kinase domains of cacao PR-1 receptor-like kinases

The PR-1 proteins (pathogenesis-related protein 1) are involved in plant defense mechanisms against various pathogens. The genome of cacao (Theobroma cacao) encodes 14 PR-1 proteins, named TcPR-1a to TcPR-1n. Two of them, TcPR-1f and TcPR-1g, have a C-terminal expansion with high similarity to protein kinase domains, suggesting a receptor-like kinase (RLK) protein architecture. Moreover, TcPR-1g is highly expressed during cacao response to Witches' Broom Disease, caused by the fungus Moniliopthora perniciosa. Here we describe a structural genomics approach to clone, express and purify the kinase domains of TcPR-1f and TcPR-1g. Escherichia coli BL21(DE3)-R3 cells were used for protein expression and co-expression of Lambda Protein Phosphatase was critical for successfully obtaining soluble recombinant protein. We expect that the ability to express and purify the kinase domains of TcPR-1f and TcPR-1g will further our understanding of the role these proteins play during cacao defense response.

Systemic RNA Interference in Planarians by Feeding of dsRNA Containing Bacteria

RNA interference (RNAi) is currently the only method available in planaria for assessing the function of particular genes. We describe here a method for performing body-wide gene knockdown, relying on dsRNA production in bacteria and subsequent delivery to planaria by feeding a liver-bacteria mixture. This method is ideal for screening many genes in parallel, in a cost-effective and reliable manner. We also describe a ligation-independent cloning strategy, which is used to rapidly transfer single genes into an RNAi vector that is also appropriate for downstream applications such as in situ hybridizations. Together, these protocols represent useful components of the current planarian molecular tool kit.

High-Throughput IgG Reformatting and Expression

We have recently described a one-step zero-background IgG reformatting method that enables the rapid reformatting of phage-displayed antibody fragments into a single-mammalian cell expression vector for full IgG expression (Chen et al. Nucleic Acids Res 42:e26, 2014). The strategy utilizes our unique positive selection method, referred to as insert-tagged (InTag) positive selection, where a positive selection marker (e.g. chloramphenicol-resistance gene) is cloned together with the antibody inserts into the expression vector. The recombinant clones containing the InTag adaptor are then positively selected without cloning background, thus bypassing the need to plate out cultures and screen colonies. This IgG reformatting method is rapid and can be automated and performed in a high-throughput (HTP) format. The use of InTag positive selection with the Dyax Fab-on-phage antibody library is demonstrated. We have further optimized the protocol for IgG reformatting since the initial publication of this method (Chen et al. Nucleic Acids Res 42:e26, 2014) and also updated the transient transfection protocol using Expi293F cells, which are described herein.

Current Overview of TALEN Construction Systems

Transcription activator-like effector (TALE) nuclease (TALEN) is the second-generation genome editing tool consisting of TALE protein containing customizable DNA-binding repeats and nuclease domain of FokI enzyme. Each DNA-binding repeat recognizes one base of double-strand DNA, and functional TALEN can be created by a simple modular assembly of these repeats. To easily and efficiently assemble the highly repetitive DNA-binding repeat arrays, various construction systems such as Golden Gate assembly, serial ligation, and ligation-independent cloning have been reported. In this chapter, we summarize the current situation of these systems and publically available reagents and protocols, enabling optimal selection of best suited systems for every researcher who wants to utilize TALENs in various research fields.

Rapid Construction of Recombinant Plasmids by QuickStep-Cloning

QuickStep-Cloning is a novel molecular cloning technique that builds upon the concepts of asymmetric PCR and megaprimer-based amplification of whole plasmid. It was designed specifically to address the major drawbacks of previously reported cloning methods. The fully optimized protocol allows for a seamless integration of a long DNA fragment into any position within a plasmid of choice, in a time-efficient and cost-effective manner, without the need of a tedious DNA gel purification, a restriction digestion, and an enzymatic ligation. QuickStep-Cloning can be completed in less than 6 h, significantly faster than most of the existing cloning methods, while retaining high efficiency.

Rapid modification of the pET-28 expression vector for ligation independent cloning using homologous recombination in Saccharomyces cerevisiae

The ability to rapidly customize an expression vector of choice is a valuable tool for any researcher involved in high-throughput molecular cloning for protein overexpression. Unfortunately, it is common practice to amend or neglect protein targets if the gene that encodes the protein of interest is incompatible with the multiple-cloning region of a preferred expression vector. To address this issue, a method was developed to quickly exchange the multiple-cloning region of the popular expression plasmid pET-28 with a ligation-independent cloning cassette, generating pGAY-28. This cassette contains dual inverted restriction sites that reduce false positive clones by generating a linearized plasmid incapable of self-annealing after a single restriction-enzyme digest. We also establish that progressively cooling the vector and insert leads to a significant increase in ligation-independent transformation efficiency, demonstrated by the incorporation of a 10.3 kb insert into the vector. The method reported to accomplish plasmid reconstruction is uniquely versatile yet simple, relying on the strategic placement of primers combined with homologous recombination of PCR products in yeast.

Ligation-independent cloning and self-cleaving intein as a tool for high-throughput protein purification

The rapid production of purified recombinant proteins has become increasingly important for countless applications. Many purification methods involve expression of target proteins in fusion to purification tags, which often must be removed from the target proteins after purification. Recently, engineered inteins have been used to create convenient self-cleaving tags for tag removal. Although intein methods can greatly simplify protein purification, commercially available expression vectors still rely on conventional restriction/ligation cloning methods for target gene insertion. We have streamlined this process by introducing Ligation-Independent Cloning (LIC) capability to our intein expression plasmids, which provides a simple method for constructing self-cleaving tag-target gene fusions. In this work, we demonstrate efficient gene insertion via this system, as well as target protein expression and purification consistent with previously reported results. Through this newly developed system, arbitrary protein genes can be rapidly incorporated into self-cleaving tag expression vectors, and their products purified using convenient platform methods.

Heat-induced fibrillation of BclXL apoptotic repressor

The BclXL apoptotic repressor bears the propensity to associate into megadalton oligomers in solution, particularly under acidic pH. Herein, using various biophysical methods, we analyze the effect of temperature on the oligomerization of BclXL. Our data show that BclXL undergoes irreversible aggregation and assembles into highly-ordered rope-like homogeneous fibrils with length in the order of mm and a diameter in the μm-range under elevated temperatures. Remarkably, the formation of such fibrils correlates with the decay of a largely α-helical fold into a predominantly β-sheet architecture of BclXL in a manner akin to the formation of amyloid fibrils. Further interrogation reveals that while BclXL fibrils formed under elevated temperatures show no observable affinity toward BH3 ligands, they appear to be optimally primed for insertion into cardiolipin bicelles. This salient observation strongly argues that BclXL fibrils likely represent an on-pathway intermediate for insertion into mitochondrial outer membrane during the onset of apoptosis. Collectively, our study sheds light on the propensity of BclXL to form amyloid-like fibrils with important consequences on its mechanism of action in gauging the apoptotic fate of cells in health and disease.