A method for generating user-defined circular single-stranded DNA from plasmid DNA using Golden Gate intramolecular ligation

Construction of user-defined long circular single stranded DNA (cssDNA) and linear single stranded DNA (lssDNA) is important for various biotechnological applications. Many current methods for synthesis of these ssDNA molecules do not scale to multikilobase constructs. Here we present a robust methodology for generating user-defined cssDNA employing Golden Gate assembly, a nickase, and exonuclease degradation. Our technique is demonstrated for three plasmids with insert sizes ranging from 2.1 to 3.4 kb, requires no specialized equipment, and can be accomplished in 5 h with a yield of 33%-43% of the theoretical. To produce lssDNA, we evaluated different CRISPR-Cas9 cleavage conditions and reported a 52 ± 8% cleavage efficiency of cssDNA. Thus, our current method does not compete with existing protocols for lssDNA generation. Nevertheless, our protocol can make long, user-defined cssDNA readily available to biotechnology researchers.

A Baculovirus Expression Vector Derived Entirely from Non-Templated, Chemically Synthesized DNA Parts

Baculovirus expression system1s are a widely used tool in recombinant protein and biologics production. To enable the possibility of genome modifications unconstrained through low-throughput and bespoke classical genome manipulation techniques, we set out to construct a baculovirus vector (>130 kb dsDNA) built from modular, chemically synthesized DNA parts. We constructed a synthetic version of Autographa californica multiple nucleopolyhedrovirus (AcMNPV) through two steps of hierarchical Golden Gate assembly. Over 140 restriction endonuclease sites were removed to enable the discrimination of the synthetic genome from native baculovirus genomes. A head-to-head comparison of our modular, synthetic AcMNPV genome with native baculovirus vectors showed no significant difference in baculovirus growth kinetics or recombinant adeno-associated virus production-suggesting that neither baculovirus replication nor very-late gene expression were compromised by our design or assembly method. With unprecedented control over the AcMNPV genome at the single-nucleotide level, we hope to ambitiously explore novel AcMNPV vectors streamlined for biologics production and development.

Modular Cloning by Golden Gate Assembly and Possible Application in Pathway Design

Preparation of expression vectors using conventional cloning strategies is laborious and not suitable for the design of metabolic pathways or enzyme cascades, which usually requires the preparation of a vector library to identify productive clones. Recently, Modular Cloning as a novel cloning technique in synthetic biology has been developed. Modular Cloning relies on Golden Gate assembly and supports preparation of individual expression vectors in one-step and one-pot reactions, thus allowing rapid generation of vector libraries. A number of Modular Cloning toolkits for specific applications has been established, providing a collection of distinct genetic elements such as promoters, ribosome binding sites and tags, that can be combined individually in one-step using defined fusion sites. Modular Cloning has been successfully applied to generate various strains for producing value-added compounds. This was achieved by orchestrating complex pathways involving up to 20 enzymes. Due to the novelty of the genetic approach, industrial applications are still rare. In addition, some applications are limited due to the lack of high-throughput screening methods. This shifts the bottleneck from library preparation to screening capacity and needs to be addressed by future developments to pave the path for the establishment of Modular Cloning in industrial applications.

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.

Base Editing in Poplar Through an Agrobacterium-Mediated Transformation Method

CRISPR-Cas9 systems have revolutionized genome editing in plants and facilitated gene knockout and functional genomic studies in woody plants, like poplar. However, in tree species, previous studies have only focused on targeting indel mutations through CRISPR-based nonhomologous end joining (NHEJ) pathway. Cytosine base editors (CBEs) and adenine base editors (ABEs) enable C-to-T and A-to-G base changes, respectively. These base editors can introduce premature stop codons and amino acid changes, alter RNA splicing sites, and edit cis-regulatory elements of promoters. Base editing systems have only been recently established in trees. In this chapter, we describe a detailed, robust, and thoroughly tested protocol for preparing T-DNA vectors with two highly efficient CBEs, PmCDA1-BE3 and A3A/Y130F-BE3, and the highly efficient ABE8e as well as delivering the T-DNA through an improved protocol for Agrobacterium-mediated transformation in poplar. This chapter will provide promising application potential for precise base editing in poplar and other trees.

PARA: A New Platform for the Rapid Assembly of gRNA Arrays for Multiplexed CRISPR Technologies

Multiplexed CRISPR technologies have great potential for pathway engineering and genome editing. However, their applications are constrained by complex, laborious and time-consuming cloning steps. In this research, we developed a novel method, PARA, which allows for the one-step assembly of multiple guide RNAs (gRNAs) into a CRISPR vector with up to 18 gRNAs. Here, we demonstrate that PARA is capable of the efficient assembly of transfer RNA/Csy4/ribozyme-based gRNA arrays. To aid in this process and to streamline vector construction, we developed a user-friendly PARAweb tool for designing PCR primers and component DNA parts and simulating assembled gRNA arrays and vector sequences.

Rapid 40 kb Genome Construction from 52 Parts through Data-optimized Assembly Design

Large DNA constructs (>10 kb) are invaluable tools for genetic engineering and the development of therapeutics. However, the manufacture of these constructs is laborious, often involving multiple hierarchical rounds of preparation. To address this problem, we sought to test whether Golden Gate assembly (GGA), an in vitro DNA assembly methodology, can be utilized to construct a large DNA target from many tractable pieces in a single reaction. While GGA is routinely used to generate constructs from 5 to 10 DNA parts in one step, we found that optimization permitted the assembly of >50 DNA fragments in a single round. We applied these insights to genome construction, successfully assembling the 40 kb T7 bacteriophage genome from up to 52 parts and recovering infectious phage particles after cellular transformation. The assembly protocols and design principles described here can be applied to rapidly engineer a wide variety of large and complex assembly targets.

Golden Gate assembly of BioBrick-compliant parts using Type II restriction endonucleases

Aims: New methods of DNA recombination that capture the principal advantages of the BioBrick standard (ease of design) and Golden Gate assembly (decreased labor) are demonstrated here. Methods & materials: Both methods employ DNA methyltransferase expression vectors, available from Addgene, that protect selected sites on different plasmids from particular Type II restriction endonucleases. No other reagents are required. Results: The 4R/2M discontinuous DNA assembly is more efficient (produces more desired recombinant plasmids) and as specific (produces few undesired recombination products) as conventional subcloning. The 5RM continuous DNA assembly is approximately as efficient and specific as conventional Golden Gate assembly, even though in vivo methylation of one plasmid is incomplete. Conclusion: Both methylase-assisted methods streamline BioBrick assembly workflows without complicating the design of synthetic parts.

Protocols for marker-free gene knock-out and knock-down in Kluyveromyces marxianus using CRISPR/Cas9

There is increased interest in strain engineering in the food and industrial yeast Kluyveromyces marxianus and a number of CRISPR/Cas9 systems have been described and used by different groups. The methods that we developed allow for very rapid and efficient inactivation of target genes using the endogenous DNA repair mechanisms of the cell. The strains and plasmids that we use are freely available, and here we provide a set of integrated protocols to easily inactivate genes and to precisely integrate DNA fragments into the genome, for example for promoter replacement, allelic swaps or introduction of point mutations. The protocols use the Cas9/gRNA expression plasmid pUCC001 and Golden Gate assembly for molecular cloning of targeting sequences. A genome-wide set of target sequences is provided. Using these plasmids in wild-type strains or in strains lacking non-homologous end-joining (NHEJ) DNA repair, the first set of protocols explain how to introduce indels (NHEJ-mediated) or precise deletions (homology-dependent repair (HDR)-mediated) at precise targets. The second set of protocols describe how to swap a promoter or coding sequence to yield a reprogrammed gene. The methods do not require the use of dominant or auxotrophic marker genes and thus the strains generated are marker-free. The protocols have been tested in multiple K. marxianus strains, are straightforward and can be carried out in any molecular biology laboratory without specialized equipment.

An Integrative Toolbox for Synthetic Biology in Rhodococcus

The development of microbial cell factories requires robust synthetic biology tools to reduce design uncertainty and accelerate the design-build-test-learn process. Herein, we developed a suite of integrative genetic tools to facilitate the engineering of Rhodococcus, a genus of bacteria with considerable biocatalytic potential. We first created pRIME, a modular, copy-controlled integrative-vector, to provide a robust platform for strain engineering and characterizing genetic parts. This vector was then employed to benchmark a series of strong promoters. We found P_M6 to be the strongest constitutive rhodococcal promoter, 2.5- to 3-fold stronger than the next in our study, while overall promoter activities ranged 23-fold between the weakest and strongest promoters during exponential growth. Next, we used an optimized variant of P_M6 to develop hybrid-promoters and integrative vectors to allow for tetracycline-inducible gene expression in Rhodococcus. The best of the resulting hybrid-promoters maintained a maximal activity of ∼50% of P_M6 and displayed an induction factor of ∼40-fold. Finally, we developed and implemented a uLoop-derived Golden Gate assembly strategy for high-throughput DNA assembly in Rhodococcus. To demonstrate the utility of our approaches, pRIME was used to engineer Rhodococcus jostii RHA1 to grow on vanillin at concentrations 10-fold higher than what the wild-type strain tolerated. Overall, this study provides a suite of tools that will accelerate the engineering of Rhodococcus for various biocatalytic applications, including the sustainable production of chemicals from lignin-derived aromatics.

Development of a Csy4-processed guide RNA delivery system with soybean-infecting virus ALSV for genome editing

BACKGROUND

A key issue for implementation of CRISPR-Cas9 genome editing for plant trait improvement and gene function analysis is to efficiently deliver the components, including guide RNAs (gRNAs) and Cas9, into plants. Plant virus-based gRNA delivery strategy has proven to be an important tool for genome editing. However, its application in soybean which is an important crop has not been reported yet. ALSV (apple latent spherical virus) is highly infectious virus and could be explored for delivering elements for genome editing.

RESULTS

To develop a ALSV-based gRNA delivery system, the Cas9-based Csy4-processed ALSV Carry (CCAC) system was developed. In this system, we engineered the soybean-infecting ALSV to carry and deliver gRNA(s). The endoribonuclease Csy4 effectively releases gRNAs that function efficiently in Cas9-mediated genome editing. Genome editing of endogenous phytoene desaturase (PDS) loci and exogenous 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) sequence in Nicotiana. benthamiana (N. benthamiana) through CCAC was confirmed using Sanger sequencing. Furthermore, CCAC-induced mutagenesis in two soybean endogenous GW2 paralogs was detected.

CONCLUSIONS

With the aid of the CCAC system, the target-specific gRNA(s) can be easily manipulated and efficiently delivered into soybean plant cells by viral infection. This is the first virus-based gRNA delivery system for soybean for genome editing and can be used for gene function study and trait improvement.

CRISPR-Cas9 Based Genome Editing in Wheat

The development and application of high precision genome editing tools such as programmable nucleases are set to revolutionize crop breeding and are already having a major impact on fundamental science. Clustered regularly interspaced short palindromic repeats (CRISPR), and its CRISPR-associated protein (Cas), is a programmable RNA-guided nuclease enabling targeted site-specific double stranded breaks in DNA which, when incorrectly repaired, result in gene knockout. The two most widely cultivated wheat types are the tetraploid durum wheat (Triticum turgidum ssp. durum L.) and the hexaploid bread wheat (Triticum aestivum L.). Both species have large genomes, as a consequence of ancient hybridization events between ancestral progenitors. The highly conserved gene sequence and structure of homoeologs among subgenomes in wheat often permits their simultaneous targeting using CRISPR-Cas9 with single or paired single guide RNA (sgRNA). Since its first successful deployment in wheat, CRISPR-Cas9 technology has been applied to a wide array of gene targets of agronomical and scientific importance. The following protocols describe an experimentally derived strategy for implementing CRISRP-Cas9 genome editing, including sgRNA design, Golden Gate construct assembly, and screening analysis for genome edits. © 2021 The Authors. Basic Protocol 1: Selection of sgRNA target sequence for CRISPR-Cas9 Basic Protocol 2: Construct assembly using Golden Gate (MoClo) assembly Basic Protocol 3: Screening for CRISPR-Cas9 genome edits Alternate Protocol: BigDye Terminator reactions for screening of CRISPR-Cas9 genome edits.

Creation of Golden Gate constructs for gene doctoring

Background

Gene doctoring is an efficient recombination-based genetic engineering approach to mutagenesis of the bacterial chromosome that combines the λ-Red recombination system with a suicide donor plasmid that is cleaved in vivo to generate linear DNA fragments suitable for recombination. The use of a suicide donor plasmid makes Gene Doctoring more efficient than other recombineering technologies. However, generation of donor plasmids typically requires multiple cloning and screening steps.

Results

We constructed a simplified acceptor plasmid, called pDOC-GG, for the assembly of multiple DNA fragments precisely and simultaneously to form a donor plasmid using Golden Gate assembly. Successful constructs can easily be identified through blue-white screening. We demonstrated proof of principle by inserting a gene for green fluorescent protein into the chromosome of Escherichia coli. We also provided related genetic parts to assist in the construction of mutagenesis cassettes with a tetracycline-selectable marker.

Conclusions

Our plasmid greatly simplifies the construction of Gene Doctoring donor plasmids and allows for the assembly of complex, multi-part insertion or deletion cassettes with a free choice of target sites and selection markers. The tools we developed are applicable to gene editing for a wide variety of purposes in Enterobacteriaceae and potentially in other diverse bacterial families.

Use YeastFab to Construct Genetic Parts and Multicomponent Pathways for Metabolic Engineering

Budding yeast, as a eukaryotic model organism, has well-defined genetic information and a highly efficient recombination system, making it a good host to produce exogenous chemicals. Since most metabolic pathways require multiple genes to function in coordination, it is usually laborious and time-consuming to construct a working pathway. To facilitate the construction and optimization of multicomponent exogenous pathways in yeast, we recently developed a method called YeastFab Assembly, which includes three steps: (1) make standard and reusable genetic parts, (2) construct transcription units from characterized parts, and (3) assemble a complete pathway. Here we describe a detailed protocol of this method.

De novo Biosynthesis of Odd-Chain Fatty Acids in Yarrowia lipolytica Enabled by Modular Pathway Engineering

Microbial oils are regarded as promising alternatives to fossil fuels as concerns over environmental issues and energy production systems continue to mount. Odd-chain fatty acids (FAs) are a type of valuable lipid with various applications: they can serve as biomarkers, intermediates in the production of flavor and fragrance compounds, fuels, and plasticizers. Microorganisms naturally produce FAs, but such FAs are primarily even-chain; only negligible amounts of odd-chain FAs are generated. As a result, studies using microorganisms to produce odd-chain FAs have had limited success. Here, our objective was to biosynthesize odd-chain FAs de novo in Yarrowia lipolytica using inexpensive carbon sources, namely glucose, without any propionate supplementation. To achieve this goal, we constructed a modular metabolic pathway containing seven genes. In the engineered strain expressing this pathway, the percentage of odd-chain FAs out of total FAs was higher than in the control strain (3.86 vs. 0.84%). When this pathway was transferred into an obese strain, which had been engineered to accumulate large amounts of lipids, odd-chain fatty acid production was 7.2 times greater than in the control (0.05 vs. 0.36 g/L). This study shows that metabolic engineering research is making progress toward obtaining efficient cell factories that produce odd-chain FAs.

Highly Efficient Single-Pot Scarless Golden Gate Assembly

Golden Gate assembly is one of the most widely used DNA assembly methods due to its robustness and modularity. However, despite its popularity, the need for BsaI-free parts, the introduction of scars between junctions, as well as the lack of a comprehensive study on the linkers hinders its more widespread use. Here, we first developed a novel sequencing scheme to test the efficiency and specificity of 96 linkers of 4-bp length and experimentally verified these linkers and their effects on Golden Gate assembly efficiency and specificity. We then used this sequencing data to generate 200 distinct linker sets that can be used by the community to perform efficient Golden Gate assemblies of different sizes and complexity. We also present a single-pot scarless Golden Gate assembly and BsaI removal scheme and its accompanying assembly design software to perform point mutations and Golden Gate assembly. This assembly scheme enables scarless assembly without compromising efficiency by choosing optimized linkers near assembly junctions.

Generation of FLIP and FLIP-FlpE Targeting Vectors for Biallelic Conditional and Reversible Gene Knockouts in Mouse and Human Cells

Rapid generation of conditional knockout models in a diploid system is challenging. Recently, CRISPR-FLIP strategy has been introduced, which facilitates the generation of biallelic conditional or reversible gene knockouts in various mammalian cell lines including mouse and human pluripotent stem cells by codelivery of the CRISPR/Cas9 system and a universal intronic cassette-FLIP and FLIP-FlpE. Here, I describe the design and cloning method of FLIP and FLIP-FlpE targeting vectors for conditional and reversible gene knockouts. This method is applicable to mouse embryonic stem cells, human induced pluripotent stem cells, and adult stem cell-derived organoids.

Rapid Assembly of gRNA Arrays via Modular Cloning in Yeast

CRISPR is a versatile technology for genomic editing and regulation, but the expression of multiple gRNAs in S. cerevisiae has thus far been limited. We present here a simple extension to the Yeast MoClo Toolkit, which enables the rapid assembly of gRNA arrays using a minimal set of parts. Using a dual-PCR, Type IIs restriction enzyme Golden Gate assembly approach, at least 12 gRNAs can be assembled and expressed from a single transcriptional unit. We demonstrate that these gRNA arrays can stably regulate gene expression in a synergistic manner via dCas9-mediated repression. This approach expands the number of gRNAs that can be expressed in this model organism and may enable the versatile editing or transcriptional regulation of a greater number of genes in vivo.

CRISPR-Act2.0: An Improved Multiplexed System for Plant Transcriptional Activation

CRISPR systems have greatly promoted research in genome editing and transcriptional regulation. CRISPR-based transcriptional repression and activation systems will be valuable for applications in engineering plant immunity, boosting metabolic production, and enhancing our knowledge of gene regulatory networks. Multiplexing of CRISPR allows multiple genes to be targeted without significant additional effort. Here, we describe our CRISPR-Act2.0 system which is an improved multiplexing transcriptional activation system in plants.

High-Throughput Allelic Replacement Screening in Bacillus subtilis

Site-directed mutagenesis is a key tool in the analysis of biological mechanisms. We have established an efficient and systematic gene targeting strategy for Bacillus subtilis based on the Golden Gate cloning methodology. Our approach permits the introduction of single or multiple point mutations or of heavily engineered alleles into the endogenous gene locus in a single step using a 96-well microtiter plate format. We have successfully applied this system for high-throughput functional screening of resized variants of the Structural Maintenance of Chromosome (Smc) protein and for exhaustive cysteine cross-linking mutagenesis. Here we describe, in detail, the experimental setup for high-throughput introduction of modifications into the B. subtilis chromosome. With minor modifications, the approach should be applicable to other bacteria and yeast.

Generating Gene Knockout Oryzias latipes and Rice Field Eel Using TALENs Method

Transcription activator-like effector nucleases (TALENs) methods based on engineered nucleases enable precise manipulations with genomic DNA. Within the field, genetic manipulation has surpassed the proof of principle stage and is now utilized in both applied strategies and performing in economic organism. The generation and study of gene modified (GM) fish using TALENs provides a novel and essential tool for fishes molecular breeding. The medaka, Oryzias latipes, is a small, freshwater fish and an idea model organism to study reproductive mechanism. Rice Field eel is a valuable model organism of high economic importance in PR China. In this chapter, we describe microinjection of Oryzias latipes and Rice Field eel embryos, in the context of preparing, evaluating, performing gene knockout and generate gene knockout fish with TALENs in detail, which are easy to prepare and proved to be efficient in targeting of a wide range of cleavage sites. Our procedure will facilitate broader applications of TALENs in freshwater aquaculture organism.

Comprehensive Profiling of Four Base Overhang Ligation Fidelity by T4 DNA Ligase and Application to DNA Assembly

Synthetic biology relies on the manufacture of large and complex DNA constructs from libraries of genetic parts. Golden Gate and other Type IIS restriction enzyme-dependent DNA assembly methods enable rapid construction of genes and operons through one-pot, multifragment assembly, with the ordering of parts determined by the ligation of Watson-Crick base-paired overhangs. However, ligation of mismatched overhangs leads to erroneous assembly, and low-efficiency Watson Crick pairings can lead to truncated assemblies. Using sets of empirically vetted, high-accuracy junction pairs avoids this issue but limits the number of parts that can be joined in a single reaction. Here, we report the use of comprehensive end-joining ligation fidelity and bias data to predict high accuracy junction sets for Golden Gate assembly. The ligation profile accurately predicted junction fidelity in ten-fragment Golden Gate assembly reactions and enabled accurate and efficient assembly of a lac cassette from up to 24-fragments in a single reaction.

A Golden Gate and Gateway double-compatible vector system for high throughput functional analysis of genes

A major research topic nowadays is to study and understand the functions of the increasing number of predicted genes that have been discovered through the complete genome sequencing of many plant species. With the aim of developing tools for rapid and convenient gene function analysis, we have developed a set of "pGate" vectors based on the principle of Golden gate and Gateway cloning approaches. These vectors combine the positive aspects of both Golden gate and Gateway cloning strategies. pGate vectors can not only be used as Golden gate recipient vectors to assemble multiple DNA fragments in a pre-defined order, but they can also work as an entry vector to transfer the assembled DNA fragment(s) to a large number of already-existing, functionally diverse, Gateway compatible destination vectors without adding additional nucleotides during cloning. We show the pGate vectors are effective and convenient in several major aspects of gene function analyses, including BiFC (Bimolecular fluorescence complementation) to analyze protein-protein interaction, amiRNA (artificial microRNA) candidate screening and as assembly of CRISPR/Cas9 (Clustered regularly interspaced short palindromic repeats, CRISPR-associated protein-9 nuclease) system elements together for genome editing. The pGate system is a practical and flexible tool which can facilitate plant gene function research.

Single Day Construction of Multigene Circuits with 3G Assembly

The ability to rapidly design, build, and test prototypes is of key importance to every engineering discipline. DNA assembly often serves as a rate limiting step of the prototyping cycle for synthetic biology. Recently developed DNA assembly methods such as isothermal assembly and type IIS restriction enzyme systems take different approaches to accelerate DNA construction. We introduce a hybrid method, Golden Gate-Gibson (3G), that takes advantage of modular part libraries introduced by type IIS restriction enzyme systems and isothermal assembly's ability to build large DNA constructs in single pot reactions. Our method is highly efficient and rapid, facilitating construction of entire multigene circuits in a single day. Additionally, 3G allows generation of variant libraries enabling efficient screening of different possible circuit constructions. We characterize the efficiency and accuracy of 3G assembly for various construct sizes, and demonstrate 3G by characterizing variants of an inducible cell-lysis circuit.

Designing and Implementing Algorithmic DNA Assembly Pipelines for Multi-Gene Systems

Advances in DNA synthesis and assembly technology allow for the high-throughput fabrication of hundreds to thousands of multi-part genetic constructs in a short time. This allows for rapid hypothesis-testing and genetic optimization in multi-gene biological systems. Here, we discuss key considerations to design and implement an algorithmic DNA assembly pipeline that provides the freedom to change nearly any design variable in a multi-gene system. In addition to considerations for pipeline design, we describe protocols for three useful molecular biology techniques in plasmid construction.

Plant Gene Regulation Using Multiplex CRISPR-dCas9 Artificial Transcription Factors

Besides genome editing, the CRISPR-Cas9-based platform provides a new way of engineering artificial transcription factors (ATFs). Multiplex of guide RNA (gRNA) expression cassettes holds a great promise for many useful applications of CRISPR-Cas9. In this chapter, we provide a detailed protocol for building advanced multiplexed CRISPR-dCas9-Activator/repressor T-DNA vectors for carrying out transcriptional activation or repression experiments in plants. We specifically describe the assembly of multiplex T-DNA vectors that can express multiple gRNAs to activate a silenced gene, or to repress two independent miRNA genes simultaneously in Arabidopsis. We then describe a "higher-order" vector assembly method for increased multiplexing capacity. This higher-order assembly method in principle allows swift stacking of gRNAs cassettes that are only limited by the loading capacity of a cloning or expression vector.

SMRT Gate: A method for validation of synthetic constructs on Pacific Biosciences sequencing platforms

Current DNA assembly methods are prone to sequence errors, requiring rigorous quality control (QC) to identify incorrect assemblies or synthesized constructs. Such errors can lead to misinterpretation of phenotypes. Because of this intrinsic problem, routine QC analysis is generally performed on three or more clones using a combination of restriction endonuclease assays, colony PCR, and Sanger sequencing. However, as new automation methods emerge that enable high-throughput assembly, QC using these techniques has become a major bottleneck. Here, we describe a quick and affordable methodology for the QC of synthetic constructs. Our method involves a one-pot digestion-ligation DNA assembly reaction, based on the Golden Gate assembly methodology, that is coupled with Pacific Biosciences' Single Molecule, Real-Time (PacBio SMRT) sequencing technology.

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.

Targeted Mutagenesis in Bombyx mori Using TALENs

Bombyx mori is a valuable model organism of high economic importance. Its genome sequence is available, as well as basic genetic and molecular genetic tools and markers. The introduction of genome editing methods based on engineered nucleases enables precise manipulations with genomic DNA, including targeted DNA deletions, insertions, or replacements in the genome allowing gene analysis and various applications. We describe here the use of TALENs which have a simple modular design of their DNA-binding domains, are easy to prepare and proved to be efficient in targeting of a wide range of cleavage sites. Our procedure often allows the production of individuals carrying homozygous mutations as early as in the G1 generation.

Engineering Customized TALENs Using the Platinum Gate TALEN Kit

Among various strategies for constructing customized transcription activator-like effector nucleases (TALENs), the Golden Gate assembly is the most widely used and most characterized method. The principle of Golden Gate assembly involves cycling reactions of digestion and ligation of multiple plasmids in a single tube, resulting in PCR-, fragmentation-, and purification-free concatemerization of DNA-binding repeats. Here, we describe the protocols for Golden Gate assembly-based TALEN construction using the Platinum Gate TALEN Kit, which allows generation of highly active Platinum TALENs.

A Versatile Microfluidic Device for Automating Synthetic Biology

New microbes are being engineered that contain the genetic circuitry, metabolic pathways, and other cellular functions required for a wide range of applications such as producing biofuels, biobased chemicals, and pharmaceuticals. Although currently available tools are useful in improving the synthetic biology process, further improvements in physical automation would help to lower the barrier of entry into this field. We present an innovative microfluidic platform for assembling DNA fragments with 10× lower volumes (compared to that of current microfluidic platforms) and with integrated region-specific temperature control and on-chip transformation. Integration of these steps minimizes the loss of reagents and products compared to that with conventional methods, which require multiple pipetting steps. For assembling DNA fragments, we implemented three commonly used DNA assembly protocols on our microfluidic device: Golden Gate assembly, Gibson assembly, and yeast assembly (i.e., TAR cloning, DNA Assembler). We demonstrate the utility of these methods by assembling two combinatorial libraries of 16 plasmids each. Each DNA plasmid is transformed into Escherichia coli or Saccharomyces cerevisiae using on-chip electroporation and further sequenced to verify the assembly. We anticipate that this platform will enable new research that can integrate this automated microfluidic platform to generate large combinatorial libraries of plasmids and will help to expedite the overall synthetic biology process.