合成生物学中不依赖限制性内切酶的分子克隆策略

随着合成生物学的兴起和发展,基因克隆和DNA大片段组装成为了常规操作。利用人工智能和液体操作机器人进行高通量的DNA组装和功能筛选已被广泛应用。传统的依赖于限制性内切酶识别位点的克隆技术对序列有选择性、步骤繁琐、实验人员的培训周期长,不利于以流水线形式进行工程化使用,已经逐步在生物工程领域内被淘汰。文中论述了一系列适于机械化操作的新一代分子克隆技术,即不依赖基因序列和连接反应克隆方法、Gibson组装、聚合酶环形延伸克隆、细胞裂解物体外无痕连接和细胞体内组装克隆。对这些方法的建立、基本原理及应用前景等方面进行了总结,并对其优缺点进行了比较。     

Cloning of linear DNAs in vivo by overexpressed T4 DNA ligase: construction of a T4 phage hoc gene display vector.

A method was developed to clone linear DNAs by overexpressing T4 phage DNA ligase in vivo, based upon recombination deficient E. coli derivatives that carry a plasmid containing an inducible T4 DNA ligase gene. Integration of this ligase-plasmid into the chromosome of such E. coli allows standard plasmid isolation following linear DNA transformation of the strains containing high levels of T4 DNA ligase. Intramolecular ligation allows high efficiency recircularization of cohesive and blunt-end terminated linear plasmid DNAs following transformation. Recombinant plasmids could be constructed in vivo by co-transformation with linearized vector plus insert DNAs, followed by intermolecular ligation in the T4 ligase strains to yield clones without deletions or rearrangements. Thus, in vitro packaged lox-site terminated plasmid DNAs injected from phage T4 were recircularized by T4 ligase in vivo with an efficiency comparable to CRE recombinase. Clones that expressed a capsid-binding 14-aa N-terminal peptide extension derivative of the HOC (highly antigenic outer capsid) protein for T4 phage hoc gene display were constructed by co-transformation with a linearized vector and a PCR-synthesized hoc gene. Therefore, the T4 DNA ligase strains are useful for cloning linear DNAs in vivo by transformation or transduction of DNAs with nonsequence-specific but compatible DNA ends.     

Replication of the Streptomyces plasmid pSN22 through single-stranded intermediates

The replication of the 11 kb conjugative multicopy Streptomyces plasmid pSN22 was analyzed. Mutation and complementation analyses indicated that the minimal region essential for plasmid replication was located on a 1.9 kb fragment of pSN22, containing a trans-acting element encoding a replication protein and a cis-acting sequence acting as a replication origin. Southern hybridization showed that minimal replicon plasmids accumulated much more single-stranded plasmid molecules than did wild-type pSN22. Only one strand was accumulated. A 500 by fragment from the pSN22 transfer region was identified which reduced the relative amount of single-stranded DNA, when added in the native orientation to minimal replicon plasmids. This 500 by DNA sequence may be an origin for second-strand synthesis. It had no effect on the efficiency of co-transformation, plasmid incompatibility, or stability. The results indicate that pSN22 replicates via single-stranded intermediates by a rolling circle mechanism.     

DNA Fragments Assembly Based on Nicking Enzyme System

A couple of DNA ligation-independent cloning (LIC) methods have been reported to meet various requirements in metabolic engineering and synthetic biology. The principle of LIC is the assembly of multiple overlapping DNA fragments by single-stranded (ss) DNA overlaps annealing. Here we present a method to generate single-stranded DNA overlaps based on Nicking Endonucleases (NEases) for LIC, the method was termed NE-LIC. Factors related to cloning efficiency were optimized in this study. This NE-LIC allows generating 3′-end or 5′-end ss DNA overlaps of various lengths for fragments assembly. We demonstrated that the 10 bp/15 bp overlaps had the highest DNA fragments assembling efficiency, while 5 bp/10 bp overlaps showed the highest efficiency when T4 DNA ligase was added. Its advantage over Sequence and Ligation Independent Cloning (SLIC) and Uracil-Specific Excision Reagent (USER) was obvious. The mechanism can be applied to many other LIC strategies. Finally, the NEases based LIC (NE-LIC) was successfully applied to assemble a pathway of six gene fragments responsible for synthesizing microbial poly-3-hydroxybutyrate (PHB).     

Harnessing homologous recombination in vitro to generate recombinant DNA via SLIC

We describe a new cloning method, sequence and ligation-independent cloning (SLIC), which allows the assembly of multiple DNA fragments in a single reaction using in vitro homologous recombination and single-strand annealing. SLIC mimics in vivo homologous recombination by relying on exonuclease-generated ssDNA overhangs in insert and vector fragments, and the assembly of these fragments by recombination in vitro. SLIC inserts can also be prepared by incomplete PCR (iPCR) or mixed PCR. SLIC allows efficient and reproducible assembly of recombinant DNA with as many as 5 and 10 fragments simultaneously. SLIC circumvents the sequence requirements of traditional methods and functions much more efficiently at very low DNA concentrations when combined with RecA to catalyze homologous recombination. This flexibility allows much greater versatility in the generation of recombinant DNA for the purposes of synthetic biology.     

Rapid Restriction Enzyme-Free Cloning of PCR Products: A High-Throughput Method Applicable for Library Construction

Herein, we describe a novel cloning strategy for PCR-amplified DNA which employs the type IIs restriction endonuclease BsaI to create a linearized vector with four base-long 5′-overhangs, and T4 DNA polymerase treatment of the insert in presence of a single dNTP to create vector-compatible four base-long overhangs. Notably, the insert preparation does not require any restriction enzyme treatment. The BsaI sites in the vector are oriented in such a manner that upon digestion with BsaI, a stuffer sequence along with both BsaI recognition sequences is removed. The sequence of the four base-long overhangs produced by BsaI cleavage were designed to be non-palindromic, non-compatible to each other. Therefore, only ligation of an insert carrying compatible ends allows directional cloning of the insert to the vector to generate a recombinant without recreating the BsaI sites. We also developed rapid protocols for insert preparation and cloning, by which the entire process from PCR to transformation can be completed in 6–8 h and DNA fragments ranging in size from 200 to 2200 bp can be cloned with equal efficiencies. One protocol uses a single tube for insert preparation if amplification is performed using polymerases with low 3′-exonuclease activity. The other protocol is compatible with any thermostable polymerase, including those with high 3′-exonuclease activity, and does not significantly increase the time required for cloning. The suitability of this method for high-throughput cloning was demonstrated by cloning batches of 24 PCR products with nearly 100% efficiency. The cloning strategy is also suitable for high efficiency cloning and was used to construct large libraries comprising more than 10⁸ clones/µg vector. Additionally, based on this strategy, a variety of vectors were constructed for the expression of proteins in E. coli, enabling large number of different clones to be rapidly generated.     

Efficient microprojectile bombardment-mediated transformation of rice using gene cassettes

This study was aimed at determining whether gene cassettes (promoter-coding sequence-terminator) can be efficiently used in microprojectile acceleration-mediated co-transformation of rice in the place of whole plasmids, and to what extent their use influences the integration and expression of the co-transferred gene of interest. Two non-linked marker genes (yfp and hph) were co-introduced by microprojectile bombardment into cells of embryogenic calli in three separate experiments. Three different DNA structures were compared for their ability to transiently and stably transform rice cells: supercoiled or linearized whole-plasmid DNA, gene cassette DNA and single-stranded gene cassette DNA coated with Escherichia coli single-stranded binding (SSB) proteins. Our results demonstrate that microprojectile bombardment-mediated transformation of rice using gene cassettes is possible without significantly reducing transformation efficiency in comparison to the use of whole-plasmid DNA. Furthermore, no obvious difference in transgene integration pattern and inheritance was observed among plants transformed with gene cassettes compared to those transformed with the whole plasmid, except that concatemerization of molecules prior to integration was rarely observed in gene cassette transformants. Received: 4 April 2001 / Accepted: 13 August 2001     

Generating In Vivo Cloning Vectors for Parallel Cloning of Large Gene Clusters by Homologous Recombination

A robust method for the in vivo cloning of large gene clusters was developed based on homologous recombination (HR), requiring only the transformation of PCR products into Escherichia coli cells harboring a receiver plasmid. Positive clones were selected by an acquired antibiotic resistance, which was activated by the recruitment of a short ribosome-binding site plus start codon sequence from the PCR products to the upstream position of a silent antibiotic resistance gene in receiver plasmids. This selection was highly stringent and thus the cloning efficiency of the GFPuv gene (size: 0.7 kb) was comparable to that of the conventional restriction-ligation method, reaching up to 4.3 × 10⁴ positive clones per μg of DNA. When we attempted parallel cloning of GFPuv fusion genes (size: 2.0 kb) and carotenoid biosynthesis pathway clusters (sizes: 4 kb, 6 kb, and 10 kb), the cloning efficiency was similarly high regardless of the DNA size, demonstrating that this would be useful for the cloning of large DNA sequences carrying multiple open reading frames. However, restriction analyses of the obtained plasmids showed that the selected cells may contain significant amounts of receiver plasmids without the inserts. To minimize the amount of empty plasmid in the positive selections, the sacB gene encoding a levansucrase was introduced as a counter selection marker in receiver plasmid as it converts sucrose to a toxic levan in the E. coli cells. Consequently, this method yielded completely homogeneous plasmids containing the inserts via the direct transformation of PCR products into E. coli cells.     

Generation of Plasmid Vectors Expressing FLAG-tagged Proteins Under the Regulation of Human Elongation Factor-1α Promoter Using Gibson Assembly

Gibson assembly (GA) cloning offers a rapid, reliable, and flexible alternative to conventional DNA cloning methods. We used GA to create customized plasmids for expression of exogenous genes in mouse embryonic stem cells (mESCs). Expression of exogenous genes under the control of the SV40 or human cytomegalovirus promoters diminishes quickly after transfection into mESCs. A remedy for this diminished expression is to use the human elongation factor-1 alpha (hEF1α) promoter to drive gene expression. Plasmid vectors containing hEF1α are not as widely available as SV40- or CMV-containing plasmids, especially those also containing N-terminal 3xFLAG-tags. The protocol described here is a rapid method to create plasmids expressing FLAG-tagged CstF-64 and CstF-64 mutant under the expressional regulation of the hEF1α promoter. GA uses a blend of DNA exonuclease, DNA polymerase and DNA ligase to make cloning of overlapping ends of DNA fragments possible. Based on the template DNAs we had available, we designed our constructs to be assembled into a single sequence. Our design used four DNA fragments: pcDNA 3.1 vector backbone, hEF1α promoter part 1, hEF1α promoter part 2 (which contained 3xFLAG-tag purchased as a double-stranded synthetic DNA fragment), and either CstF-64 or specific CstF-64 mutant. The sequences of these fragments were uploaded to a primer generation tool to design appropriate PCR primers for generating the DNA fragments. After PCR, DNA fragments were mixed with the vector containing the selective marker and the GA cloning reaction was assembled. Plasmids from individual transformed bacterial colonies were isolated. Initial screen of the plasmids was done by restriction digestion, followed by sequencing. In conclusion, GA allowed us to create customized plasmids for gene expression in 5 days, including construct screens and verification.     

Classifying DNA assembly protocols for devising cellular architectures

DNA assembly is one of the most fundamental techniques in synthetic biology. Efficient methods can turn traditional DNA cloning into time-saving and higher efficiency practice, which is a foundation to accomplish the dreams of synthetic biologists for devising cellular architectures, reprogramming cellular behaviors, or creating synthetic cells. In this review, typical strategies of DNA assembly are discussed with special emphasis on the assembly of long and multiple DNA fragments into intact plasmids or assembled compositions. Constructively, all reported strategies were categorized into in vivo and in vitro types, and protocols are presented in a functional and practice-oriented way in order to portray the general nature of DNA assembly applications. Significantly, a five-step blueprint is proposed for devising cell architectures that produce valuable chemicals.     

Cloning Should Be Simple: Escherichia coli DH5α-Mediated Assembly of Multiple DNA Fragments with Short End Homologies

Numerous DNA assembly technologies exist for generating plasmids for biological studies. Many procedures require complex in vitro or in vivo assembly reactions followed by plasmid propagation in recombination-impaired Escherichia coli strains such as DH5α, which are optimal for stable amplification of the DNA materials. Here we show that despite its utility as a cloning strain, DH5α retains sufficient recombinase activity to assemble up to six double-stranded DNA fragments ranging in size from 150 bp to at least 7 kb into plasmids in vivo. This process also requires surprisingly small amounts of DNA, potentially obviating the need for upstream assembly processes associated with most common applications of DNA assembly. We demonstrate the application of this process in cloning of various DNA fragments including synthetic genes, preparation of knockout constructs, and incorporation of guide RNA sequences in constructs for clustered regularly interspaced short palindromic repeats (CRISPR) genome editing. This consolidated process for assembly and amplification in a widely available strain of E. coli may enable productivity gain across disciplines involving recombinant DNA work.     

Fast genome editing in Bacillus subtilis

Bacillus subtilis is a model organism for Gram‐positive bacteria and widely used in the study of cellular functions and processes including protein secretion, sporulation, and signal transduction. It is also an important industrial host for the production of proteins and chemicals. Generally, genome editing of B. subtilis often needs the construction of integration vectors in Escherichia coli, linearizing the constructed plasmids, and subsequent transformation of the linear deoxyribonucleic acid via natural competence or electroporation. In this work, we examined the feasibility to directly transform and integrate B. subtilis using linear deoxyribonucleic acid from Gibson assembly without the need for cloning in E. coli. Linear deoxyribonucleic acid of 8–10 kb showed the highest transformation efficiency which was similar to that of using linearized plasmids constructed in E. coli. This method shortens the overall process from 1 week to 1 day and allows the integration of multiple genes in one step, providing a simple and fast method for genome editing in B. subtilis.     

几种新型植物基因表达载体的构建方法

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

Improved method for high-efficiency electrotransformation of Escherichia coli with the large BAC plasmids

High transformation competency of Escherichia coli is one of the critical factors in the bacterial artificial chromosome (BAC)-based DNA library construction. Many electroporation protocols have been published until now, but the majority of them was optimized for transformation of small plasmids. Large plasmids with a size above 50 kbp display reduced transformation efficiency and thereby require specific conditions in the preparation and electroporation of electrocompetent cells. In the present work, we have optimized the parameters critical to the application of BAC DNA electrotransformation into E. coli. Systematic evaluation of electroporation variables has revealed several key factors like temperature of growth, media supplements, washing buffer, and cell concentration. Improvements made in the transformation protocol have led to electrocompetent cells with transformation efficiency up to 7?×?10⁸ transformants per microgram of 120 kbp BAC plasmid DNA. We have successfully used in-house prepared competent cells, the quality of which is comparable with those produced by different companies, in the construction of metagenomic libraries from the soil. Our protocol can also be beneficial for other application with limited DNA source.     

Replication of the Streptomyces plasmid pSN22 through single-stranded intermediates

The replication of the 11 kb conjugative multicopy Streptomyces plasmid pSN22 was analyzed. Mutation and complementation analyses indicated that the minimal region essential for plasmid replication was located on a 1.9 kb fragment of pSN22, containing a trans-acting element encoding a replication protein and a cis-acting sequence acting as a replication origin. Southern hybridization showed that minimal replicon plasmids accumulated much more single-stranded plasmid molecules than did wild-type pSN22. Only one strand was accumulated. A 500 by fragment from the pSN22 transfer region was identified which reduced the relative amount of single-stranded DNA, when added in the native orientation to minimal replicon plasmids. This 500 by DNA sequence may be an origin for second-strand synthesis. It had no effect on the efficiency of co-transformation, plasmid incompatibility, or stability. The results indicate that pSN22 replicates via single-stranded intermediates by a rolling circle mechanism.     

The Selection of Recombinant Binary Plasmids Generated by Gateway® LR Cloning in the Escherichia coli Strain C2110

Gateway^® cloning is widely used in molecular biology laboratories. Various binary vectors used for Agrobacterium-mediated plant transformation have been modified as destination vectors that are convenient for the sub-cloning of targeted genes from Entry plasmids. However, when the destination and Entry plasmids have the same antibiotic resistance genes for bacterial selection, the non-recombinant Entry plasmid in the LR reaction mixture can compete with the recombinant destination plasmid during bacterial transformation and selection. Methods for the effective selection of recombinant destination plasmids are highly desirable. In this study, we demonstrated that Escherichia coli strain C2110, which is defective in DNA polymerase I (pAL1), could be used to select a recombinant binary destination plasmid with a RK2 replication origin, while the replication of the Entry plasmid with a ColE1 replication origin was inhibited. Plasmid DNA isolated from C2110 by a traditional mini-prep kit was used for restriction enzyme digestion, DNA sequencing, and Arabidopsis protoplast transfection. The binary plasmid in C2110 was also efficiently mobilized into Agrobacterium tumefaciens via the tri-parental conjugation method.     

AQUA Cloning: A Versatile and Simple Enzyme-Free Cloning Approach

Assembly cloning is increasingly replacing conventional restriction enzyme and DNA-ligase-dependent cloning methods for reasons of efficiency and performance. Here, we describe AQUA (advanced quick assembly), a simple and versatile seamless assembly cloning approach. We demonstrate the applicability and versatility of AQUA Cloning in selected proof-of-principle applications including targeted insertion-, deletion- and site-directed point-mutagenesis, and combinatorial cloning. Furthermore, we show the one pot de novo assembly of multiple DNA fragments into a single circular plasmid encoding a complex light- and chemically-regulated Boolean A NIMPLY B logic operation. AQUA Cloning harnesses intrinsic in vivo processing of linear DNA fragments with short regions of homology of 16 to 32 bp mediated by Escherichia coli. It does not require any kits, enzymes or preparations of reagents and is the simplest assembly cloning protocol to date.     

Culture of Escherichia coli in SOC medium improves the cloning efficiency of toxic protein genes

In this paper, we report a useful protocol for cloning toxic protein genes. Use of the SOC medium, which is a glucose-containing rich medium, significantly improved the transformation efficiency of a recombinant plasmid containing a toxic plant subtilase SaSBT1 cDNA. Both glucose and rich nutrients present in the SOC medium prevented the unintended activation of the lac promoter carried on the cloning vector, and led to significantly improved transformation efficiency of recombinant plasmids containing toxic protein genes and an increased rate of transformant growth.     

One-step sequence- and ligation-independent cloning as a rapid and versatile cloning method for functional genomics studies

We developed one-step sequence- and ligation-independent cloning (SLIC) as a simple, cost-effective, time-saving, and versatile cloning method. Highly efficient and directional cloning can be achieved by direct bacterial transformation 2.5 min after mixing any linearized vector, an insert(s) prepared by PCR, and T4 DNA polymerase in a tube at room temperature.     

A comparison of strategies for multiple-gene co-transformation via hairy root induction

Hairy root is a transformed root tissue in which transfer DNA (T-DNA) is inserted in the genome by Agrobacterium rhizogenes. To establish a system for multiple-gene co-transformation in hairy roots, we evaluated four different strategies using A. rhizogenes. The genes gusA and mgfp5 were located in separate plasmids, which were transformed into two different batches of A. rhizogenes (strategy 2AR) or a single batch (strategy 2BV). The two reporter genes were also inserted in one T-DNA (strategy 1TD) or two different T-DNAs (strategy 2TD) in a binary vector. Over 90 % of infected Nicotiana tabacum leaf discs formed hairy roots in all four groups, which was not significantly different from the infection efficiency of wild-type A. rhizogenes. Proportions of co-transformed hairy roots with strategies 2AR, 2BV, 1TD, and 2TD were 65.4, 40.0, 78.6, and 82.1 %, respectively, which indicated that all of the strategies were suitable for co-transformation of multiple genes. High variation in growth rate and heterologous protein expression indicated that further screening is required to identify the clone with the highest productivity. Our results indicated that strategies 1TD and 2TD achieved the highest co-transformation efficiency. Combination with strategy 2AR or 2BV provides additional options for co-transformation of multiple transgenes.