A new cloning system for Bacillus subtilis comprising elements of phage, plasmid and transposon vectors

A new cloning system for Bacillus subtilis was devised which makes use of a combination of Tn917-containing phage SP beta derivatives and Tn917-containing Escherichia coli-B. subtilis shuttle plasmids. This system allows the initial cloning of genes in single copy, via 'prophage transformation', with a selection for complementation of mutational defects in B. subtilis hosts and permits subsequent transfer of the cloned material by homologous recombination to low-copy and high-copy vectors that replicate in both B. subtilis and E. coli. Because cloned sequences are adjacent to pB322-derived DNA in the recombinant phages, inserts can also be 'rescued' directly from the phage DNA after digestion with appropriate restriction enzymes, circularization of the fragments by ligation and transformation of an E. coli recipient. Two genomic libraries of B. subtilis chromosomal Sau3A-generated partial-digest fragments in the size ranges of 5-8 kb and 8-10 kb were constructed and screened for the complementation of mutations aroI906, cysA14, dal-1, glyB133, metC3, purA16, purB33, thrA5, trpC2 and recE4. In all cases, specialized transducing phages carrying inserts that complemented the selected markers were recovered. Inserts complementing the dal-1 and trpC2 mutations could be transferred from recombinant phages to Tn917-containing plasmids by homologous recombination without in vitro subcloning. Another insert complementing the purB33 mutation was rescued directly into E. coli from a recombinant phage DNA.     

Optimized protocols and plasmids for in vivo cloning in yeast

Saccharomyces cerevisiae has proven a valuable system for the construction of plasmids via gap repair or in vivo cloning. The method allows cloning with superior accuracy and without the need to use restriction enzymes. However, despite its remarkable efficiency, the process may occasionally require the screening of large number of candidates. We have previously reported that by simply using shuttle plasmids that allow blue/white selection in Escherichia coli, it is possible to pre-select for positive clones. Here, we demonstrate that the same strategy can be used to assemble plasmids from several ectopic DNA fragments, which are all introduced in yeast cells by a simple transformation step. Further, to facilitate the subcloning of the fragment cloned into other targeting or expression vectors, the multi-cloning sites of three shuttle plasmids have been extended to include fifteen new restriction enzyme recognition sites.     

A protocol for DNA fragment extraction from polyacrylamide gels

A simple and efficient method of purifying linear plasmid DNA from contaminating DNA fragments is described. Both vector and insert containing plasmids may be used without extensive purification, in particular without cesium chloride centrifugation. Careful deproteinization with phenol-chloroform allows efficient restriction enzyme digestion. Fragment separation can be performed immediately after restriction endonuclease digestion in a single 6% polyacrylamide gel. Extraction of DNA fragments from the gel is easy and gives a good yield. The DNA may be used for ligation and transformation without further purification.     

Insertional restoration of beta-galactosidase alpha-complementation (white-to-blue colony screening) facilitates assembly of synthetic genes

The assembly of synthetic genes from oligodeoxynucleotides can be an inefficient process. Upon ligation of a synthetic assembly into a plasmid vector and transformation of an Escherichia coli host, it is often found that only a minor fraction of the putative recombinant plasmids contains synthetic sequences. Moreover, the synthetic sequences cloned are often altered versions of those originally designed. We have designed a biological test to detect those plasmids that contain synthetic sequences of the proper length, termini and reading frame. The test is the reversal of the beta-galactosidase alpha-complementation (blue-to-white) test used to detect the insertion of DNA segments into the polylinker sequences of the phage M13 mp, plasmids pUC, and related vectors. We begin with a modified vector defective in alpha-complementation and use insertion of the synthetic DNA segment to restore alpha-complementation. The alpha-complementation activity of the original vector (e.g., pUC18) was first abolished by a frameshift or DNA insertion within the polylinker sequence of the lacZ' gene segment. The alpha-complementation was then restored by insertion of the synthetic DNA sequence between the cohesive ends generated by digestion of two polylinker restriction sites. Formation of blue colonies requires the insertion of a DNA segment of appropriate length and termini to reconstruct the lacZ' open reading frame and thus is much more selective than the usual insertional inactivation strategy. We show that this 'insertional restoration' screening method markedly enhances the proper assembly of synthetic genes and describe manipulations to readily and reliably frameshift various polylinker sequences.     

Rapid and efficient subcloning of DNA without dephosphorylation or gel electrophoresis

Conventional subcloning into plasmid vectors often involves dephosphorylation, gel electrophoresis, DNA extraction, and purification to isolate the target insert and the cleaved plasmid. This is not only time-consuming but very often problematic. We have developed strategies that can circumvent these steps by mixing digested donor and recipient plasmids together for ligation. These strategies capitalizes on: (1) the ability to enhance the ligation efficiency of desired DNA fragments into the target vector by the generation and removal of small (<50 bp) fragments from nontarget DNA using peripheral restriction sites and spin column technology and (2) the elimination of undesired ligation products after ligation by using the Lac Z gene, differences in antibiotic resistance among plasmid vectors, and unique restriction sites situated in nontarget DNA fragments.     

The assembly of large BACs by in vivo recombination

We have developed a method for recombining bacterial artificial chromosomes (BACs) and P1 artificial chromosomes (PACs) containing large genomic DNA fragments into a single vector using the Cre-lox recombination system from bacteriophage P1 in vivo. This overcomes the limitations of in vitro methods for generating large constructs based on restriction digestion, ligation, and transformation of DNA into Escherichia coli cells. We used the method to construct a human artificial chromosome vector of 404 kb encompassing long tracts of alpha satellite DNA, telomeric sequences, and the human hypoxanthine phosphoribosyltransferase gene. The specificity of Cre recombinase for loxP sites minimizes the possibility of intramolecular rearrangements, unlike previous techniques using general homologous recombination in E. coli, and makes our method compatible with the presence of large arrays of repeated sequences in cloned DNA. This methodology may also be applied to retrofitting PACs or BACs with markers and functional sequences.     

Partial-digest DNA sequencing.

A technique called partial-digest sequencing that permits DNA of 4-6 kb in length to be sequenced without subcloning is described. The method exploits the specific cuts introduced by partial digestion with restriction endonucleases that have 4-base recognition sites to produce ordered ladders of PCR-amplified fragments. The staggered ends contain PCR primers and can thus be individually sequenced using conventional methods to yield overlapping sequences covering the entire region. This method should have significant impact on both large and small DNA sequencing projects and find many applications in general manipulations in which ordered sets of deletions need to be produced.     

A convenient and robust method for construction of combinatorial and random mutant libraries

Here we describe a convenient and robust ligase-independent method for construction of combinatorial and random mutant libraries. The homologous genes flanked by plasmid-derived DNA sequences are fragmented, and the random fragments are reassembled in a self-priming polymerase reaction to obtain chimeric genes. The product is then mixed with linearized vector and two pairs of flanking primers, followed by assembly of the chimeric genes and linearized vector by PCR to introduce recombinant plasmids of a combinatorial library. Commonly, it is difficult to find proper restriction sites during the construction of recombinant plasmids after DNA shuffling with multiple homologous genes. However, this disadvantage can be overcome by using the ligase-independent method because the steps of DNA digestion and ligation can be avoided during library construction. Similarly, DNA sequences with random mutations introduced by error-prone PCR can be used to construct recombinant plasmids of a random mutant library with this method. Additionally, this method can meet the needs of large and comprehensive DNA library construction.     

Construction of recombinant vaccinia viruses using PUV-inactivated virus as a helper

Recombinant vaccinia viruses (VVs) are widely used as expression vectors in molecular biology and immunology and are now under evaluation for gene therapy. The current techniques for inserting foreign DNA into the large VV genome are based on either homologous recombination between transfer plasmids and VVgenomes or direct DNA ligation and packaging using replication-deficient poxviruses. Here, we describe efficient new versions of both methods that produce 90%-100% of the recombinant viruses. In the new homologous recombination method, VV DNA "arms" obtained by NotI digestion and intact transfer plasmids were used for co-transfection. In the direct DNA ligation method, foreign DNA was inserted into a unique NotI restriction site of the VVgenome. In both methods, the generation of recombinant viruses was carried out in cells infected with a non-replicating, psoralen-UV (PUV)-inactivated helper VV. The convenience of these new techniques is demonstrated by the construction of recombinant VVs that produce E. coli beta-galactosidase. An important feature of these strategies is that any VV strain can be used as a helper virus after PUV inactivation.     

Generation of deletion subclones for sequencing by partial digestion with restriction endonucleases

A method for creating a group of deletion subclones for DNA sequencing by partial digestion of M13 bacteriophage constructions is outlined. The M13 construct is linearized at a unique site and then subjected to partial digestion with a frequent-cutting restriction endonuclease. The insert is truncated at different locations. The vector DNA is also partially digested. The products of a single partial digestion are repaired, recircularized by ligation, and used for bacterial transfection to generate subclones with a spectrum of deletions in the insert; most deletions in the vector DNA will disrupt vital viral genes and will thus disappear in the transfection. The subclones are sorted by size by gel electrophoresis of single-stranded viral DNA. This method is simpler and thus may be more reliable than established subcloning schemes.     

Plasmids of the cyanobacterium Synechocystis 6701

Abstract Plasmids were obtained from Synechocystis 6701 using a lysis method that employed a hemicellulase digestion procedure. Eight major bands were observed in the initial preparation. Four of the smaller plasmids were isolated using preparative agarose electrophoresis gels and identified by restriction endonuclease analysis. Chromosomal DNA was screened with 15 restriction enzymes and 6 ( Eco RI, Sst I, Hpa I, Bst EII, Acc I, and Bgl II) were effective. Analysis of DNA fragments from plasmids pSCY 1–4 indicated that each plasmid was unique and that their approximate sizes were 5, 7.5, 13.5 and 15 kb, respectively. Digestion of pSCY 1 and pSCY 4 with Bgl II produced DNA fragments that may be used to construct a conjugation vector for this unicellular cyanobacterium.     

Plasmids with easily excisable cat gene cartridges

New cat-cassette-containing vectors based on kanamycin-resistance-encoding plasmids, pHSG298/299, were constructed. They were designed to facilitate the subcloning of the promoterless cat gene into frequently used plasmids, including those with an ampicillin-resistance marker. In plasmids pCAT10-pCAT40, the cat gene cartridges are flanked by polylinker sequences and can be excised by double digestion with pairs of appropriate restriction enzymes. Translation stop condons in all three reading frames are located upstream from the AUG start codon of the pCAT40 cartridge; the latter can also be excised by a single digestion with the enzymes, SalI, PstI, or HindIII.     

Development and use of cloning systems for Bacteroides fragilis: cloning of a plasmid-encoded clindamycin resistance determinant.

Chimeric plasmids able to replicate in Bacteroides fragilis or in B. fragilis and Escherichia coli were constructed and used as molecular cloning vectors. The 2.7-kilobase pair (kb) cryptic Bacteroides plasmid pBI143 and the E. coli cloning vector pUC19 were the two replicons used for these constructions. Selection of the plasmid vectors in B. fragilis was made possible by ligation to a restriction fragment bearing the clindamycin resistance (Ccr) determinant from a Bacteroides R plasmid, pBF4;Ccr was not expressed in E. coli. The chimeric plasmids ranged from 5.3 to 7.3 kb in size and contained at least 10 unique restriction enzyme recognition sites suitable for cloning. Transformation of B. fragilis with the chimeric plasmids was dependent upon the source of the DNA; generally 10(5) transformants micrograms-1 of DNA were recovered when plasmid purified from B. fragilis was used. When the source of DNA was E. coli, there was a 1,000-fold decrease in the number of transformants obtained. Two of the shuttle plasmids not containing the pBF4 Ccr determinant were used in an analysis of the transposon-like structure encoding Ccr in the R plasmid pBI136. This gene encoding Ccr was located on a 0.85-kb EcoRI-HaeII fragment and cloned nonselectively in E. coli. Recombinants containing the gene inserted in both orientations at the unique ClaI site within the pBI143 portion of the shuttle plasmids could transform B. fragilis to clindamycin resistance. These results together with previous structural data show that the gene encoding Ccr lies directly adjacent to one of the repeated sequences of the pBI136 transposon-like structure.     

Use of DNA-protein interaction to isolate specific genomic DNA sequences.

We describe a simple and rapid method for the isolation of specific genomic DNA sequences recognized by DNA-binding proteins. This procedure consists of four steps: (1) restriction enzyme digestion and size fractionation of genomic DNA; (2) DNA--protein binding using the gel mobility-shift assay; (3) ligation of isolated DNA fragments followed by transformation of Escherichia coli; and (4) screening of recombinant clones for inserts containing specific DNA--protein binding sequences. We have used this protocol to isolate human DNA sequences, 100-200 bp in size, that are recognized by both partially purified and affinity purified proteins. Unlike other procedures designed to identify genomic target sequences, the method described does not require polymerase chain reaction or successive immunoprecipitations.     

An efficient method for generation and subcloning of tandemly repeated DNA sequences with defined length, orientation and spacing.

Tandemly repeated DNA sequences generated from single synthetic oligonucleotide monomers are useful for many purposes. With conventional ligation procedures low yields and random orientation of oligomers makes cloning of defined repeated sequences difficult. We solved these problems using 2 bp overhangs to direct orientation and random incorporation of linkers containing restriction sites during ligation. Ligation products are amplified by PCR using the linker oligonucleotides as primers. Restriction digestion of the PCR products generate multimer distributions whose length is controlled by the monomer/linker ratio. The concatenated DNA fragments of defined length, orientation and spacing can be directly used for subcloning or other applications without further treatment.     

利用DREAM设计和同源重组进行一步定点突变

目的：建立基于DREAM设计和同源重组的简便、快速定点突变方法。方法：设计两条包含突变的反向PCR（inverse PCR）引物,使其5'端互补从而产生同源重组,同时使用DREAM设计方案在上述引物中引入限制性内切酶位点以便突变子筛选。用能扩增长片段的高保真耐热 DNA聚合酶扩增全长的质粒DNA,直接转化大肠杆菌。转化到细菌中的全长质粒DNA PCR产物可利用其末端同源序列发生同源重组而环化。利用引入的酶切位点方便地进行突变子的筛选。结果：我们用该方法成功地对长度大于7 kb的质粒进行了定点突变。结论：本定点突变无需任何突变试剂盒和特殊的试剂,只需一步反应即可完成;利用DREAM设计使克隆筛选简便可靠,高保真耐热DNA聚合酶可保证多数突变子克隆不发生意外突变,而该酶扩增长片段的能力使该方法适合于大多数质粒不经亚克隆直接突变。     

Construction and characterization of three yeast-Escherichia coli shuttle vectors designed for rapid subcloning of yeast genes on small DNA fragments

We have constructed three new subcloning plasmid vectors, pRC1, pRC2, and pRC3, derived from pKC7, which allow the rapid, single-step subcloning of yeast genes. Subcloning with these vectors utilizes a partial digestion with Sau3A to generate a quasi-random set of DNA fragments from the original plasmid. All three vectors contain a kanamycin resistance gene. Therefore, if the original cloned yeast DNA fragment is present in a vector that does not specify kanamycin resistance, the subclone pool can be propagated in Escherichia coli in the presence of kanamycin to select against parent plasmids that escaped restriction by Sau3A. Selection by complementation in yeast yields a collection of plasmids with smaller yeast DNA inserts containing the gene of interest. In the vectors pRC2 and pRC3, constructed from pRC1, the unique BamHI site is located within an intact tetracycline resistance gene, thus making it possible to screen bacterial transformants for those containing recombinant plasmid molecules. Vectors pRC2 and pRC3 also contain the yeast 2 micrometers DNA replication origin, and thus are more stable than plasmids carrying only the TRP1-associated replicator (ars1).     

A novel method for producing partial restriction digestion of DNA fragments by PCR with 5-methyl-CTP.

Partial digestion of DNA fragments is a standard procedure for subcloning analysis and for generating restriction maps. We have developed a novel method to generate a partial digestion for any DNA fragment that can be amplified by PCR. The method involves the incorporation of 5-methyl-dCTP into the PCR product to protect most of the restriction sites. As a result, complete digestion of the modified PCR products with a 5-methyl-dCTP-sensitive enzyme will produce an array of restriction fragments equivalent to a partial restriction enzyme digestion reaction done on unmethylated PCR products. This method reduces the time and material needed to produce partially-digested DNA fragments by traditional methods. Furthermore, using fluorescein-labeled primers in the reaction, we were able to detect the fluorescein-labeled end fragments resulting from the enzyme digestion using a fluorimager or anti-fluorescein-AP antibody and thus determine the restriction maps.