An improved method for fast, robust, and seamless integration of DNA fragments into multiple plasmids

We describe an improved, universal method for the seamless integration of DNA fragments into plasmids at any desired position. The protocol allows in vitro joining of insert and linearized plasmid at terminal homology regions using the BD In-Fusion cloning system. According to the standard BD In-Fusion protocol, vectors are linearized by restriction enzyme digestion. Linearization of plasmids by polymerase chain reaction (PCR), instead of restriction enzyme digestion, extends the usefulness of the method by rendering it independent of restriction endonuclease recognition sites and by allowing seamless insertion of DNA fragments at any position, without introduction of unwanted nucleotides flanking the site of insertion. The combination of PCR linearization of plasmids and BD In-Fusion technology has shown to be very useful for the insertion of genes into the expression regions of multiple plasmids for the heterologous expression of proteins in Escherichia coli. Hands-on time is minimal and there is no need for preparative gel electrophoresis. The protocol is very simple and only involves PCR and liquid handling steps. The method should therefore theoretically have a good potential for automation.     

Modular construction of plasmids through ligation-free assembly of vector components with oligonucleotide linkers

We have developed a modular method of plasmid construction that can join multiple DNA components in a single reaction. A nicking enzyme is used to create 5' and 3' overhangs on PCR-generated DNA components. Without the use of ligase or restriction enzymes, components are joined using oligonucleotide linkers that recognize the overhangs. By specifying the sequences of the linkers, desired components can be assembled in any combination and order to generate different plasmid vectors.     

Cloning multiple copies of a DNA segment

A method for self-ligation of DNA segments, which is based on the rotational non-equivalence of ends produced by AvaI cleavage, has been developed. Using this method and an initiator molecule to encourage the formation of long polymers, we have obtained a plasmid containing 34 repeats of a 123-bp rat DNA segment. All of the repeats are in the same orientation, and the plasmid is quite stable. It should be possible to polymerize any DNA segment by this method. Potential uses of the procedure include production of large amounts of small, homogeneous DNAs for physical studies such as X-ray crystallography, and increasing the expression of cloned genes in bacteria.     

Artificial transposable elements in the study of the ends of IS1

We have constructed artificial IS1-based transposons by attaching synthetic oligodeoxynucleotides, corresponding to the sequence of the ends of IS1, to a selectable DNA segment ['omega' fragment; Prentki and Krisch, Gene 29 (1984) 303-313]. These transposons were used to examine the sequence requirements at the ends for IS1 transposition. We show here that a 24- to 28-bp sequence from the left or right ends of IS1 is capable of transposition when present at both ends of the omega fragment in the correct orientation. Transposition activity requires the presence of an intact IS1 in cis on the same plasmid molecule. In trans, however, neither resident genomic copies of IS1, nor copies carried by a compatible, high-copy-number plasmid present in the same cell, complement the artificial transposons efficiently. Transposition frequencies in the presence of a cis-complementing IS1 are, however, similar to those of the naturally occurring IS1-based transposon, Tn9. In addition, transposition results in a 9-bp duplication in the target DNA molecule as is usually the case for insertion of the intact IS1. Using this system, we have obtained evidence indicating that the activity of a synthetic IS1 end is not determined exclusively by its sequence, but can be strongly enhanced by a second, wild-type end used in the transposition event. The data also show that single base pair mutations can exhibit a cumulative effect in reducing transposition activity.     

DNA splicing by directed ligation (SDL)

Splicing by directed ligation (SDL) is a method of in-phase joining of PCR-generated DNA fragments that is based on a pre-designed combination of class IIS restriction endonuclease recognition and cleavage sites. Since these enzymes cleave outside of their recognition sites, the resulting sticky end can have any desired sequence, and the site itself can be removed and does not appear in the final spliced DNA product. SDL is based on the addition of class IIS recognition sites onto primers used to amplify DNA sequences. Cleavage of the PCR products results in elimination of the recognition site-containing flanking sequences and leaves the DNA fragments crowned with protruding ends. With careful design of the sticky ends, several segments can be ligated together in a predetermined order in a single reaction. SDL requires fewer rounds of amplification than overlap extension methods, and is particularly useful for creating a series of recombinants that differ in one segment.     

Characterization of DNA end joining in a mammalian cell nuclear extract: junction formation is accompanied by nucleotide loss, which is limited and uniform but not site specific.

Mammalian cells have a marked capacity to repair double-strand breaks in DNA, but the molecular and biochemical mechanisms underlying this process are largely unknown. A previous report has described an activity from mammalian cell nuclei that is capable of multimerizing blunt-ended DNA substrates (R. Fishel, M.K. Derbyshire, S.P. Moore, and C.S.H. Young, Biochimie 73:257-267, 1991). In this report, we show that nuclear extracts from HeLa cells contain activities which preferentially join linear plasmid substrates in either a head-to-head or tail-to-tail configuration, that the joining reaction is covalent, and that the joining is accompanied by loss of sequence at the junction. Sequencing revealed that there was a loss of a uniform number of nucleotides from junctions formed from any one type of substrate. The loss was not determined by any simple site-specific mechanism, but the number of nucleotides lost was affected by the precise terminal sequence. There was no major effect on the efficiency or outcome of the joining reaction with substrates containing blunt ends or 3' or 5' protruding ends. Using a pair of plasmid molecules with distinguishable restriction enzyme sites, we also observed that blunt-ended DNA substrates could join with those containing protruding 3' ends. As with the junctions formed between molecules with identical ends, there was uniform loss of nucleotides. Taken together, the data are consistent with two models for the joining reaction in which molecules are aligned either throughout most of their length or by using small sequence homologies located toward their ends. Although either model can explain the preferential formation of head-to-head and tail-to-tail products, the latter predicts the precise lossof nucleotides observed. These activities are found in all cell lines examined so far and most likely represent an important repair activity of the mammalian cell.     

Cloning and template activity of the origins of replication of phage phi 29 DNA

A 73-bp fragment from the left end of phi 29 DNA and a 269-bp fragment from the right end have been cloned in plasmids pPLc28 and pKK223-3, respectively, after removal of the terminal protein p3 by treatment with piperidine. In addition, the 73- and 269-bp fragments were cloned together in plasmid pKK223-3 in such a way that the two termini of phi 29 DNA were joined. Treatment of the latter recombinant plasmid with AhaIII releases several fragments, two of which contain the phi 29 DNA terminal sequences at the DNA end. These two fragments initiated replication specifically at the ends of the DNA giving rise to the formation of the p3-dAMP complex. The activity was about 15% of that obtained with phi 29 DNA-protein p3. All remaining recombinant plasmids were essentially inactive when tested as templates either in circular form or after cutting in such a way that placed the origin of phi 29 DNA replication close but not at the DNA end.     

Joining of nonhomologous DNA double strand breaks in vitro.

Extracts of Xenopus laevis eggs can efficiently join ends of duplex DNA that differ in structure and sequence. This was analysed by recircularisation of linear plasmid DNA molecules with dissimilar termini, generated by successive cuts with two different restriction enzymes within the pSP65 polylinker. Use of various enzymes provided blunt ended or 4 nucleotides long 3' and 5' protruding single strand (PSS) termini which were successfully joined in vitro in any tested combination. Sequence analysis of numerous junctions from cloned reaction products of 7 terminus combinations reveal: apart from very rare base exchanges and single nucleotide insertions less than 10% deletions (1 to 18 nucleotides long) were detected. Blunt/PSS or 3'PSS/5'PSS terminus pairs undergo simple "blunt end" joining which preserves PSS ends by fill-in. In contrast, equally polar 3'PSS/3'PSS or 5'PSS/5'PSS terminus pairs are joined by a complex mode: PSS ends overlap by a defined number of nucleotides, set by matching basepairs. Even one basematch suffices to define the setting. This then determines the final mismatch repair and fill-in pattern. We propose that yet unknown terminal DNA-binding proteins stabilize the energetically highly unfavorable configuration of single matching basepairs and help to support defined overlap structures.     

Plasmid pACYC184 contains an ssi signal for initiation of single-strand phage DNA replication

Using the plaque assay system for screening the single-strand (ss) initiation determinant (ssi) sequences, we have found that 119-bp region in pACYC184, a derivative of the plasmid P15A of Escherichia coli, can direct such ss DNA initiation. This region is located downstream from the P15A origin of replication and conserves consensus sequences of the ssi signals found in the other plasmids. Signals for ss DNA initiation are defined as nucleotide sequences present on ss DNA templates and required for priming DNA synthesis. The direction of chain elongation in DNA synthesis is opposite to that of the leading strand. In this region, we found a potential stem-and-loop structure. The 119-bp DNA segment of plasmid pACYC184 cloned in f1R199 filamentous phage could direct rifampicin-resistant conversion of the ss DNA to the double-stranded replicative form.     

Organization and evolution of naphthalene catabolic pathways: sequence of the DNA encoding 2-hydroxychromene-2-carboxylate isomerase and trans-o-hydroxybenzylidenepyruvate hydratase-aldolase from the NAH7 plasmid.

The sequence of a 2,437-bp DNA segment from the naphthalene upper catabolic pathway operon of plasmid NAH7 was determined. This segment contains three large open reading frames designated nahQ', nahE, and nahD. The first of these is the 3' end of an open reading frame that has no known function, the second (993 bp) encodes trans-o-hydroxybenzylidenepyruvate hydratase-aldolase (deduced molecular weight, 36,640), and the third (609 bp) encodes 2-hydroxychromene-2-carboxylate isomerase (deduced molecular weight, 23,031). This DNA has a high degree of sequence homology (greater than 91% for the first 2161 bp) with a DNA segment from the dox (dibenzothiophene oxidation) operon of Pseudomonas sp. strain C18, which encodes a pathway analogous to that encoded by NAH7. However, 84 bp downstream from nahD, the last gene in the nah operon, this homology ends. This 84-bp sequence at the downstream end of nah and dox homology has 76% homology to a sequence that occurs just upstream of the nah promoter in NAH7. These directly repeated 84-bp sequences thus encompass the upper-pathway nah operon and constitute the ends of a highly conserved region.     

Ligase-free subcloning: a versatile method to subclone polymerase chain reaction (PCR) products in a single day.

Often, it is convenient to subclone polymerase chain reaction (PCR) products into a plasmid vector for subsequent replication in bacteria, but conventional subcloning methods often fail. We report a rapid and versatile method to subclone PCR products directionally into a specific site of virtually any plasmid vector. The procedure requires only four primers, does not require DNA ligase, and may be accomplished in a single day. Ligase-free subcloning is performed by incorporating into the PCR primers sequences at the 5' ends that result in PCR products whose 3' ends are complementary to the 3' ends of the recipient linearized plasmid. The PCR product and the linearized plasmid are spliced together in a second PCR reaction in which Taq polymerase extends the complementary overlapping 3' ends (ligation by overlap extension). Denaturation followed by heterologous reannealing and cyclization results in a cyclic recombinant plasmid with two nicks that may be used directly to transform competent Escherichia coli. In our hands, ligase-free subcloning is rapid, and offers many advantages over existing strategies.     

Molecular cloning of the terminal hairpin of vaccinia virus DNA as an imperfect palindrome in an Escherichia coli plasmid

The genome of vaccinia virus is a linear duplex molecule of approximately 185 kb with hairpins at each end that link the complementary strands. The hairpins, which exist in two forms that are inverted and complementary in sequence, were isolated as XbaI restriction fragments and converted to a linear intermolecular duplex structure by denaturation and reannealing. The latter was then stably cloned as a 142-bp imperfect palindrome in an Escherichia coli plasmid. The insert was excised from the plasmid and the palindrome was extended on both sides by ligating it to the adjacent vaccinia virus DNA segment. The resulting fragment was cloned as a 278-bp imperfect palindrome. Restriction endonuclease analysis and DNA sequencing indicated the absence of any deletions or rearrangements. After excision from the plasmid, the palindrome was converted by heating and rapid cooling to the original two hairpin forms. In this manner, large quantities of vaccinia virus telomeres may be obtained for physical and biochemical studies.     

Effects of mutation position on frequency of marker rescue by homologous recombination.

Homologous recombination between transferred and chromosomal DNA can be used for mapping mutations by marker rescue, i.e., by identifying which segment of wild-type DNA can recombine with the mutant chromosomal gene and restore normal function. In order to define how much the fragments should overlap each other for reliable mapping, we have measured how the frequency of marker rescue is affected by the position of the chromosomal mutation relative to the ends of the transferred DNA fragments. For this purpose, we used several DNA fragments to effect marker rescue in two mutant hybridomas which bear mutations 673 bp apart in the exons encoding the second and third constant region domains of the immunoglobulin mu heavy chain. The frequency of marker rescue decreased greatly when the mutation was located near one of the ends of the fragments, the results indicating that fragments should be designed to overlap by at least several hundred base pairs. Possible explanations for this "end effect" are considered.     

IS50-mediated inverse transposition: specificity and precision

The IS50 elements, which are present as inverted repeats in the kanamycin-resistance transposon, Tn5, can move in unison carrying with them any interstitial DNA segment. In consequence, DNA molecules such as a lambda::Tn5 phage genome are composed of two overlapping transposons - the kan segment bracketed by IS50 elements (Tn5), and lambda bracketed by IS50 elements. During direct transposition, mediated by IS50 "O" (outside) ends, the kan gene is moved and the lambda vector is left behind. During inverse transposition, mediated by the "I" (inside) ends of the IS50 elements, the lambda vector segment is moved and the kan gene is left behind. Direct transposition is several orders of magnitude more frequent than inverse transposition (Isberg and Syvanen, 1981; Sasakawa and Berg, 1982). We assessed the specificity and precision of the rare events mediated by pairs of I ends by mapping and sequencing independent inverse transpositions from a lambda::Tn5 phage into the amp and tet genes of plasmid pBR322. Using restriction analyses, 32 and 40 distinct sites of insertion were found among 46 and 72 independent inverse transpositions into the amp and tet genes, respectively. Eleven sites were used in two or more insertion events, and the two sites in tet used most frequently corresponded to major hotspots for the insertion of the Tn5 (by direct transposition). The sequences of 22 sites of inverse transposition (including each of the sites used more than once) were determined, in eleven cases by analyzing both pBR322-IS50 junctions, and in eleven others by sequencing one junction. The sequence of the "I" end of IS50 was preserved and 9-bp target sequence duplications were present in every case analyzed. GC pairs were found at each end of the target sequence duplication in ten of the eleven sites used more than once, and also in seven of the other eleven sites. Our data indicate that transposition mediated by pairs of "I" ends is similar in its specificity and precision to the more frequent transposition mediated by IS50 "O" ends.     

Development of the SapI/AarI Incision Mediated Plasmid Editing Method

Plasmid engineering and molecular cloning is a virtually ubiquitous tool in biology. Although various methods have been developed for ligating DNA molecules or targeted mutagenesis of plasmids, each has its limitations. Many of the commonly used laboratory strategies are inefficient, while commercially available kits are quite costly and often specialized for highly specific circumstances. Here, we describe the SapI/AarI incision mediated plasmid editing (SIMPLE) method, which allows users to perform site-directed mutagenesis, deletions, and even short insertions into any plasmid in a single PCR reaction, using just one restriction enzyme. In addition, the SIMPLE method can be adapted to insert any sized DNA fragment into a vector using a two-step PCR approach, and can be used to ligate any number of DNA fragments with non-compatible ends in the specific order desired. The SIMPLE method provides researches an efficient and powerful tool with a broad range of applications for molecular cloning.     

LoxP-directed cloning: use of Cre recombinase as a universal restriction enzyme.

We have developed a novel way to use the Cre/loxP system for in vitro manipulation of DNA and a technique to clone DNA into circular episomes. The method is fast, reliable, and allowsflexible cloning of DNA fragments into episomes containing a loxP site. We show that a loxP site can serve as a universal target site to clone a DNA fragment digested with any restriction enzyme(s). This technique abolishes the need for compatible restriction sites in cloning vectors and targets by generating custom-designed 5' 3', or blunt ends in the desired orientation and reading frame in the vector Therefore, this method eliminates the limitations encountered when DNA fragments are cloned into vectors with a confined number of cloning sites. The 34-bp loxP sequence assures uniqueness, even when large episomes are manipulated. We present three examples, including the manipulation of a bacterial artificial chromosome. Because DNA manipulation takes place at a loxP site, we refer to this technique as loxP-directed cloning.     

Nonhomologous DNA end joining in Schizosaccharomyces pombe efficiently eliminates DNA double-strand-breaks from haploid sequences.

Cells of higher eucaryotes are known to possess mechanisms of illegitimate recombination which promote the joining between nonhomologous ends of broken DNA and thus may serve as basic tools of double-strand-break (DSB) repair. Here we show that cells of the fission yeast Schizosaccharomyces pombe also contain activities of nonhomologous DNA end joining resembling the ones found in higher eucaryotes. Nonhomologous end joining activities were detected by transformation of linearized self-replicating plasmids in yeast cells employing a selection procedure which only propagates transformants carrying recircularized plasmid molecules. Linear plasmid substrates were generated by duplicate restriction cuts carrying either blunt ends or 3' or 5' protruding single strands (PSS) of 4 nt which were efficiently joined in any tested combination. Sequence analysis of joined products revealed that junctional sequences were shortened by 1 to 14 nt. Two mechanisms may account for junction formation (i) loss of terminal nucleotides from PSS tails to produce blunt ends which can be joined to abutting ends and (ii) interactions of DNA termini at patches of sequence homologies (1-4 bp) by formation of overlap intermediates which are subsequently processed. A general feature of the yeast joining system is that end joining can only be detected in the absence of sequence homology between the linear substrate and host genome. In the presence of homology, nonhomologous DNA end joining is efficiently competed by activities of homologous recombination.     

Construction and transduction of a shuttle vector bearing the cos site of Streptomyces phage phi C31 and determination of its cohesive ends

A plasmid has been constructed which is a bifunctional vector for Escherichia coli and for streptomycetes, containing the cos site of Streptomyces phage phi C31. It can be efficiently transduced into S. lividans 66 and into several other Streptomyces species. The nucleotide sequence of a 311-bp DNA fragment containing the cohesive ends has been determined. The cohesive ends consist of 10 bases protruding at the 3'-end of the phage genome.     

Effective method of oligonucleotide-controlled mutagenesis of DNA fragments

A procedure has been designed for changing specific nucleotides in a DNA sequence with efficiency. The method involves the use of the specially constructed cloning vectors pBRS1, pHS1, and pHS2. These plasmids are derivatives of pBR322 in which the EcoRI-HindIII region has been replaced by synthetic duplexes carrying SmaI, HpaI and XhoI sites, in addition to EcoRI and HindIII sites. The DNA fragment to be mutagenized is cloned in pHS1 (or pBRS1, or pHS2) using restriction sites close to the SmaI and HpaI sites. The recombinant plasmid obtained is digested with one of these enzymes to produce double-stranded DNA with blunt ends. This linear DNA is a substrate for exonuclease III (or T4 DNA polymerase). The digestion under controlled conditions produces duplex with protruding single-stranded 5'-regions which include the site of the desired mutation. The synthesis of DNA by DNA-polymerase I (Klenow's fragment), primed in part by the synthetic oligonucleotide containing the desired mutation, leads to the linear heteroduplex. The closed circular heteroduplex is formed by ligation. After transformation into E. coli, DNA replication generates homoduplexes, some of which contain the mutation. Colony hybridization with the same 32P-labeled oligonucleotide is used to select mutants. The yield of the mutants is 10-20%. This technique can be extended to replicative form of M13 vectors. It can be also applied to any DNA sequence which has a unique site of restriction endonuclease generating blunt ends.