Direct cloning and transplanting of large DNA fragments from Escherichia coli chromosome
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We applied a resistance split-fusion strategy to increase the in vivo direct cloning efficiency mediated by Red recombination. The cat cassette was divided into two parts: cma (which has a homologous sequence with cmb) and cmb, each of which has no resistance separately unless the two parts are fused together. The cmb sequence was integrated into one flank of a target cloning region in the chromosome, and a linear vector containing the cma sequence was electroporated into the cells to directly capture the target region. Based on this strategy, we successfully cloned an approximately 48 kb DNA fragment from the E. coli DH1-Z chromosome with a positive frequency of approximately 80%. Combined with double-strand breakage-stimulated homologous recombination, we applied this strategy to successfully replace the corresponding region of the E. coli DH36 chromosome and knock out four non-essential genomic regions in one step. This strategy could provide a powerful tool for the heterologous expression of microbial natural product biosynthetic pathways for genome assembly and for the functional study of DNA sequences dozens of kilobases in length.Keywords:
Cloning (programming)
Cloning vector
Bacterial artificial chromosome
In vitro recombination
T ransformation- a ssociated r ecombination (TAR) can be exploited in yeast to clone human DNAs. TAR cloning was previously accomplished using one or two telomere-containing vectors with a common human repeat(s) that could recombine with human DNA during transformation to generate yeast artificial chromosomes (YACs). On basis of the proposal that broken DNA ends are more recombinogenic than internal sequences, we have investigated if TAR cloning could be applied to the generation of circular YACs by using a single centromere vector containing various human repeats at opposite ends. Transformation with these vectors along with human DNA led to the efficient isolation of circular YACs with a mean size of ≈150 kb. The circular YACs are stable and they can be easily separated from yeast chromosomes or moved into bacterial cells if the TAR vector contains an Escherichia coli F-factor cassette. More importantly, circular TAR cloning enabled the selective isolation of human DNAs from monochromosomal human–rodent hybrid cell lines. Although <2% of the DNA in the hybrid cells was human, as much as 80% of transformants had human DNA YACs when a TAR cloning vector contained Alu repeats. The level of enrichment of human DNA was nearly 3000-fold. A comparable level of enrichment was demonstrated with DNA isolated from a radiation hybrid cell line containing only 5 Mb of human DNA. A high selectivity of human DNA cloning was also observed for linear TAR cloning with two telomere vectors. No human–rodent chimeras were detected among YACs generated by TAR cloning. The results with a circular TAR cloning vector or two vectors differed from results with a single-telomere vector in that the latter often resulted in a series of terminal deletions in linear YACs. This could provide a means for physical mapping of cloned material.
Yeast artificial chromosome
Cloning (programming)
In vitro recombination
Cloning vector
Shuttle vector
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Minimal plasmids play an essential role in many intermediate steps in molecular biology. For example, they can be used to assemble building blocks in synthetic biology or be used as intermediate cloning plasmids that are ideal for PCR-based mutagenesis methods. A small backbone also opens up for additional unique restriction enzyme cloning sites. Here we describe the generation of pICOz, a 1185-bp fully functional high-copy cloning plasmid with an extended multiple cloning site. We believe that this is the smallest high-copy cloning vector ever described.
Cloning (programming)
Cloning vector
Multiple cloning site
Restriction site
Synthetic Biology
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Recombination cloning encompasses a set of technologies that transfer gene sequences between vectors through site-specific recombination. Due in part to the instability of linear DNA in bacteria, both the initial capture and subsequent transfer of gene sequences is often performed using purified recombination enzymes. However, we find linear DNAs flanked by loxP sites recombine efficiently in bacteria expressing Cre recombinase and the lambda Gam protein, suggesting Cre/lox recombination of linear substrates can be performed in vivo. As one approach towards exploiting this capability, we describe a method for constructing large (>1 x 10(6) recombinants) libraries of gene mutations in a format compatible with recombination cloning. In this method, gene sequences are cloned into recombination entry plasmids and whole-plasmid PCR is used to produce mutagenized plasmid amplicons flanked by loxP. The PCR products are converted back into circular plasmids by transforming Cre/Gam-expressing bacteria, after which the mutant libraries are transferred to expression vectors and screened for phenotypes of interest. We further show that linear DNA fragments flanked by loxP repeats can be efficiently recombined into loxP-containing vectors through this same one-step transformation procedure. Thus, the approach reported here could be adapted as general cloning method.
FLP-FRT recombination
In vitro recombination
Cre recombinase
Cloning (programming)
Cre-Lox recombination
Site-specific recombination
Amplicon
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Functional genomics require manipulation and modification of large fragments of the genome. Such manipulation has only recently become more efficient due to the discovery of different techniques based on homologous recombination. However, certain limitations of these strategies still exist since insertion of homology arms (HAs) is often based on amplification of DNA sequences with PCR. Large quantities of PCR products longer than 4–5 kb can be difficult to obtain and the risk of mutations or mismatches increases with the size of the template that is being amplified. This can be overcome by adding HAs by conventional cloning techniques, but with large fragments such as entire genes the procedure becomes time-consuming and tedious. Second, homologous recombination techniques often require addition of antibiotic selection genes, which may not be desired in the final construct. Here, we report a method to overcome the size and selection marker limitations by a two- or three-step procedure. The method can insert any fragment into small or large episomes, without the need of an antibiotic selection gene. We have humanized the mouse luteinizing hormone receptor gene (Lhcgr) by inserting a ∼55 kb fragment from a BAC clone containing the human Lhcgr gene into a 170 kb BAC clone comprising the entire mouse orthologue. The methodology is based on the rationale to introduce a counter-selection cassette flanked by unique restriction sites and HAs for the insert, into the vector that is modified. Upon enzymatic digestion, in vitro or in Escherichia coli, double-strand breaks are generated leading to recombination between the vector and the insert. The procedure described here is thus an additional powerful tool for manipulating large and complex genomic fragments.
Recombineering
Insert (composites)
FLP-FRT recombination
In vitro recombination
Restriction digest
Bacterial artificial chromosome
Selectable marker
Cloning (programming)
Homology
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We applied a resistance split-fusion strategy to increase the in vivo direct cloning efficiency mediated by Red recombination.
The cat cassette was divided into two parts: cma and cmb (has a homologous sequence
with cma ). Each of them has no resistance separately
unless the two parts are fused together. The cmb fragment
was first integrated into a side of the target cloning region, then
a linear cma -containing plasmid vector was electroporated
into the cells to directly capture the target region. Based on this
strategy, we successfully cloned a DNA fragment about 48 kb from E. coli DH1-Z chromosome with positive frequency of about
80%. Then, combined with double-strand breakage-stimulated homologous
recombination, we applied this strategy to replace the corresponding
region of E. coli DH36 chromosome and knock out four
nonessential genomic regions at one time. This strategy provides a
powerful tool for the heterologous expression of microbial natural
product biosynthetic pathways, for genome assembly and for the function
study of large DNA sequence.
Cloning (programming)
Cite
Citations (1)
The precise assembly of defined DNA sequences into plasmids is an essential task in bioscience research. While a number of molecular cloning techniques have been developed, many methods require specialized expensive reagents or laborious experimental procedure. Not surprisingly, conventional cloning techniques based on restriction digestion and ligation are still commonly used in routine DNA cloning. Here, we describe a simple, fast, and economical cloning method based on RecA- and RecET-independent in vivo recombination of DNA fragments with overlapping ends using E. coli. All DNA fragments were prepared by a 2-consecutive PCR procedure with Q5 DNA polymerase and used directly for transformation resulting in 95% cloning accuracy and zero background from parental template plasmids. Quantitative relationships were established between cloning efficiency and three factors–the length of overlapping nucleotides, the number of DNA fragments, and the size of target plasmids–which can provide general guidance for selecting in vivo cloning parameters. The method may be used to accurately assemble up to 5 DNA fragments with 25 nt overlapping ends into relatively small plasmids, and 3 DNA fragments into plasmids up to 16 kb in size. The whole cloning procedure may be completed within 2 days by a researcher with little training in cloning. The combination of high accuracy and zero background eliminates the need for screening a large number of colonies. The method requires no enzymes other than Q5 DNA polymerase, has no sequence restriction, is highly reliable, and represents one of the simplest, fastest, and cheapest cloning techniques available. Our method is particularly suitable for common cloning tasks in the lab where the primary goal is to quickly generate a plasmid with a pre-defined sequence at low costs.
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Multiple cloning site
Restriction digest
In vitro recombination
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Restriction site
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The design of large scale DNA sequencing projects such as genome analysis demands a new approach to sequencing strategy, since neither a purely random nor a purely directed method is satisfactory. We have developed a strategy that combines these two methods in a way that preserves the advantages of both while avoiding their particular limitations. Computer simulations showed that a specific balance of random and directed sequencing was required for the most efficient strategy, termed the Janus strategy, which has been used in the Escherichia coli genome sequencing project. This approach depended on obtaining sequence easily from either strand of a cloned insert, and was facilitated by inversion of the insert in the engineered M13 vector Janus, by site-specific recombination. The inversion was accomplished simply by growth on the appropriate host strain, when the DNA strand incorporated into the new single stranded phage was complementary to that in the original phage, and was sequenced by the same simple protocol as the first strand.
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Hybrid genome assembly
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Natural genetic materials contain many biosynthetic gene clusters encoding potentially valuable natural products, many of which can be used directly without codon optimization or other manipulations.With the development of synthetic biology, several DNA assembly standards have been proposed, conveniently facilitating the reuse of natural materials.Among these standards, the iBrick assembly standard was developed by our laboratory to manipulate large DNA fragments, employing two homing endonucleases.Considering the difficulty of cloning large iBrick parts using conventional endonuclease-mediated restriction and ligation methods, we herein present a new method, known as iCatch, which readily captures biosynthetic gene clusters.As the clusters cloned by iCatch have the prefix and suffix of the iBrick standard, they serve as new iBrick parts and are therefore conducive to further editing and assembly with the iBrick standard.iCatch employs the natural homologous recombination system to flank the region of interest with I-SceI and PI-PspI recognition sites, after which the genome is digested with I-SceI or PI-PspI and the fragments are then self-ligated to clone the target DNA fragments.We used this method to successfully capture the actinorhodin biosynthetic cluster from Streptomyces coelicolor and then heterologously expressed this cluster in a thermophilic Streptomyces strain.We propose that iCatch can be used for the cloning of DNA sequences that are dozens of kilobases in length, facilitating the heterologous expression of microbial natural products.Moreover, this cloning methodology can be a complementary tool for the iBrick standard, especially in applications requiring the manipulation of large DNA fragments.
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In vitro recombination
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Synthetic Biology
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Abstract The study of protein en masse , or functional proteomics, depends on the availability of full‐length cDNAs in appropriate expression‐ready plasmid vectors for protein expression and functional analysis. Recombinational cloning is a universal cloning technique based on site‐specific recombination that is independent of the insert DNA sequence to be cloned, which differentiates this method from the classical restriction enzyme‐based cloning methods. Recombinational cloning enables rapid and efficient parallel transfer of DNA inserts into multiple expression systems. This unit summarizes strategies for generating expression‐ready clones using two of the most popular recombinational cloning technologies, now commercially available from Invitrogen (Gateway) and BD Clontech (Creator).
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PCR-based amplification of annotated genes has allowed construction of expression clones at genome-scale using classical and recombination-based cloning technologies. However, genome-scale expression and purification of proteins for down-stream applications is often limited by challenges such as poor expression, low solubility, large size of multi-domain proteins, etc. Alternatively, DNA fragment libraries in expression vectors can serve as the source of protein fragments with each fragment encompassing a function of its whole protein counterpart. However, the random DNA fragmentation and cloning result in only 1 out of 18 clones being in the correct open-reading frame (ORF), thus, reducing the overall efficiency of the system. This necessitates the selection of correct ORF before expressing the protein fragments. This paper describes a highly efficient ORF selection system for DNA fragment libraries, which is based on split beta-lactamase protein fragment complementation. The system has been designed to allow seamless transfer of selected DNA fragment libraries into any downstream vector systems using a restriction enzyme-free cloning strategy. The strategy has been applied for the selection of ORF using model constructs to show near 100% selection of the clone encoding correct ORF. The system has been further validated by construction of an ORF-selected DNA fragment library of 30 genes of M. tuberculosis. Further, we have successfully demonstrated the cytosolic expression of ORF-selected protein fragments in E. coli.
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In vitro recombination
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