A PCR-free cloning method for the targeted φ80 Int-mediated integration of any long DNA fragment, bracketed with meganuclease recognition sites, into the Escherichia coli chromosome

The genetic manipulation of cells is the most promising strategy for designing microorganisms with desired traits. The most widely used approaches for integrating specific DNA-fragments into the Escherichia coli genome are based on bacteriophage site-specific and Red/ET-mediated homologous recombination systems. Specifically, the recently developed Dual In/Out integration strategy enables the integration of DNA fragments directly into specific chromosomal loci (Minaeva et al., 2008). To develop this strategy further, we designed a method for the precise cloning of any long DNA fragments from the E. coli chromosome and their targeted insertion into the genome that does not require PCR. In this method, the region of interest is flanked by I-SceI rare-cutting restriction sites, and the I-SceI-bracketed region is cloned into the unique I-SceI site of an integrative plasmid vector that then enables its targeted insertion into the E. coli chromosome via bacteriophage φ80 Int-mediated specialized recombination. This approach allows any long specific DNA fragment from the E. coli genome to be cloned without a PCR amplification step and reproducibly inserted into any chosen chromosomal locus. The developed method could be particularly useful for the construction of marker-less and plasmid-less recombinant strains in the biotechnology industry.     

Molecular cloning and DNA sequencing of the radC gene of Escherichia coli K-12.

The radC102 mutation that sensitizes E. coli K-12 cells to ultraviolet light, ionizing radiations and alkylating agents was localized between the fpg and pyrE genes at 81.7 min on the bacterial chromosome. E. coli strain BH20 (radC+, fpg-1::KnR) has a 10.5-kb EcoRI/KpnI DNA fragment spanning the region from pyrE to the insertion mutation fpg-1::KnR. The proximity of the radC gene to this insertion mutation provided a strategy to isolate the radC+ gene based on the cloning of radC+ and fpg-1::KnR on the same DNA fragment using the resistance to kanamycin as a selector. A library of EcoRI/KpnI DNA fragments of E. coli strain BH20 was inserted into pUC19. One recombinant plasmid conferring resistance to kanamycin was selected and named pRCV10. The pRCV10 plasmid partially restores the resistance to UV-radiation when transformed into SR1187 (radC102), but sensitizes the wild-type strain to the same treatment. The radC102 complementing region was localized on a 1.2-kb BglII/BglII DNA fragment which was sequenced. The DNA sequence complementing the radC102 mutation contained an ATG translation start codon with an open reading frame of 297 base pairs which encodes a polypeptide of Mr 11,500. The order of the genes in this region of the E. coli chromosome is: fpg--rpmBG--radC--pyrE.     

Gene cloning, structural gene and promoter identification, and active assay of the phosphatidylcholine synthase of Pseudomonas sp. strain 593

Pseudomonas sp. strain 593, a soil bacterium, is able to use exogenous choline to synthesize phosphatidylcholine via phosphatidylcholine synthase (Pcs). A 2020 bp DNA fragment that hybridized to a Pcs probe was cloned. This fragment contained a large open reading frame (ORF) with two potential ATG start sites that would encode for 293 and 231 amino acid proteins. Fragments containing the two ORFs encoded Pcs when they were inserted into the expression vector pET23a and expressed under the control of the T7 promoter in Escherichia coli BL21(DE3) pLysS. However, when the two ORFs were inserted into the cloning vector pMD18-T and expressed without control of the plasmid promoter in E. coli DH5α, only the larger clone exhibited Pcs activity. This suggested that the larger fragment contained a native promoter driving expression of the smaller ORF. A promoter activity assay, in which DNA fragments were inserted into the promoter-probe plasmid pCB182 and β-galactosidase activity of E. coli transformants was tested, demonstrated that a promoter is indeed present in the DNA region. All results together indicate that the 696 bp ORF, not the larger 897 bp ORF, encodes the Pcs in Pseudomonas sp. strain 593 and carries a promoter in front of its 5' terminus.     

An insertion of Escherichia coli transposable element IS1K into the site immediately before tetracycline-resistance determinant of Bacillus subtilis chromosomal DNA fragment in cloning in E. coli

In cloning in Escherichia coli C600 of a 4.5-kbp HindIII DNA fragment with the tetracycline-resistance determinant (tetBS908) from Bacillus subtilis GSY908 chromosome using a plasmid vector, a 5.2-kbp HindIII DNA fragment was also isolated at a ratio of 2 to 89. The two independently obtained 5.2-kbp fragments were an insertion derivative of the 4.5-kbp fragment and carried E. coli transposable element ISlK, which was inserted at the same site immediately before tetBS908 in the same direction. For the ISlK insertions, the 8-bp sequence CAAATTTT was used as a target, this having no similarity to any published sequences.     

A place for everything: chromosomal integration of large constructs

We have developed an easy, reliable two-step method for the insertion of large DNA fragments into any desired location in the E. coli chromosome. The method is based on the recombineering of a small (～1.3 kbp) "Landing Pad" into the chromosome at the insertion site, to which the large construct is subsequently delivered via I-SceI endonuclease excision from a donor plasmid. To demonstrate the power of this method, we here show the insertion of a fragment containing the entire lac operon (～9 kbp) into four predefined novel locations in the E. coli chromosome, a feat not possible with existing technologies. In addition, the chromosomal breaks induced by landing pad excision provide sufficient selective pressure that positive selection by antibiotics is unnecessary, making precise, exact insertion without extraneous sequence possible.     

小鼠白细胞介素4基因的化学合成、克隆与表达

利用381A型DNA合成仪,分29个寡聚核苷酸片段化学合成了小鼠IL-4全基因,共442bp。以pUC12质粒作为载体,将所有合成片段分前后两组进行磷酸化、退火、连接和克隆,经过菌落原位杂交、酶切鉴定和质粒DNA序列分析,分别得到了含有小鼠IL-4前后两半基因片段的两种重组质粒,回收前半基因片段,插入到含有后半基因重组质粒的EcoRI和PstI酶切位点之间,成功地得到了含有小鼠IL-4全基因的重组质粒pFR101。将全合成基因插入到质粒pSM53中,得表达质粒pFR105,转化大肠杆菌TAP106,根据IL-4对CTLL细胞的作用,肯定了TAP106(pFR105)细菌中有小鼠IL-4活性蛋白的表达。     

Evidence that the clindamycin-erythromycin resistance gene of Bacteroides plasmid pBF4 is on a transposable element.

We constructed a shuttle vector, pE5-2, which can replicate in both Bacteroides spp. and Escherichia coli. pE5-2 contains a cryptic Bacteroides plasmid (pB8-51), a 3.8-kilobase (kb) EcoRI-D fragment from the 41-kb Bacteroides fragilis plasmid pBF4, and RSF1010, an IncQ E. coli plasmid. pE5-2 was mobilized by R751, an IncP E. coli plasmid, between E. coli strains with a frequency of 5 X 10(-2) to 3.8 X 10(-1) transconjugants per recipient. R751 also mobilized pE5-2 from E. coli donors to Bacteroides uniformis 0061RT and Bacteroides thetaiotaomicron 5482 with a frequency of 0.9 X 10(-6) to 2.5 X 10(-6). The Bacteroides transconjugants contained only pE5-2 and were resistant to clindamycin and erythromycin. Thus, the gene for clindamycin and erythromycin resistance must be located within the Eco RI-D fragment of BF4. A second recombinant plasmid, pSS-2, which contained 33 kb of pBF4 (including the EcoRI-D fragment and contiguous regions) could also be mobilized by R751 between E. coli strains. In some transconjugants, a 5.5-kb (+/- 0.3 kb) segment of the pBF4 portion of pSS2 was inserted into one of several sites on R751. In some other transconjugants this same 5.5-kb segment was integrated into the E. coli chromosome. This segment could transfer a second time onto R751. Transfer was RecA independent. The transferred segment included the entire EcoRI-D fragment, and thus the clindamycin-erythromycin resistance determinant, from pBF4.     

Cloning and sequencing of the gerD gene of Bacillus subtilis

A Tn917 insertion in the same region of the chromosome as gerD gave rise to a mutant (ger-97) with a germination phenotype similar to that of two gerD mutants which germinate abnormally in a range of germinants. The insertion and two gerD mutations were cotransformed with ribosomal protein genes rpoB, rpsE and rpsI. DNA cloned from one side of the insertion carried the 16S end of the ribosomal RNA operon rrnI. These data were consistent with the order rpoB-rpsE-rpsI-gerD/ger-97::Tn917-rrnI. Insertion into the wild-type chromosome of a plasmid carrying DNA adjacent to the insertion permitted the recovery of a 1.8 kb fragment of DNA which complemented ger-97::Tn917 and the gerD mutations. The DNA nucleotide sequence of the region of this fragment at which Tn917 had inserted revealed a 555 bp open reading frame, preceded by a ribosome-binding site and potential sigma E and sigma A promoter regions and encoding a predicted polypeptide of 21,117 Da. This polypeptide was largely hydrophilic but contained a hydrophobic region at the N-terminus resembling a signal peptide.     

Transfer of the Ti plasmid from Agrobacterium tumefaciens into Escherichia coli cells

We have screened strains of Agrobacterium tumefaciens for spontaneous mutants showing constitutive transfer of the nopaline Ti plasmid pTiC58 during conjugation. The Ti plasmid derivatives obtained could be transferred not only to A. tumefaciens but also to E. coli cells. The Ti plasmid cannot survive as a freely replicating plasmid in E. coli, but it can occasionally integrate into the E. coli chromosome. However, insertion in tandem of plasmids carrying fd replication origins (pfd plasmids) into the T-DNA provides an indicator for all transfer events into E. coli cells, providing fd gene 2 protein is present in these cells. This viral protein causes the excision of one copy of the pfd plasmid and allows its propagation in the host cell. By using this specially designed Ti plasmid, which was also made constitutive in transfer functions, we found plasmid exchange among A. tumefaciens strains and between A. tumefaciens and E. coli cells to be equally efficient. A Ti plasmid with repressed transfer functions was transferred to E. coli with a rate similar to the low frequency at which it was transferred to A. tumefaciens. The expression of transfer functions of plasmid RP4 either in A. tumefaciens or in E. coli did not increase the transfer of the Ti plasmid into E. coli cells, nor did the addition of acetosyringone, an inducer of T-DNA transfer to plant cells. The results show that A. tumefaciens can transfer the Ti plasmid to E. coli with the same efficiency as within its own species. Conjugational transmission of extrachromosomal DNA like the narrow-host-range Ti plasmid may often not only occur among partners allowing propagation of the plasmid, but also on a 'try-all' basis including hosts which do not replicate the transferred DNA.     

Rapid mapping of transposon insertion and deletion mutations in the large Ti-plasmids of Agrobacterium tumefaciens.

A procedure is presented, that has allowed the rapid assignment of transposon Tn1 and Tn7 insertion sites in the large (130 Md) nopaline Ti-plasmid pTiC58, to specific restriction enzyme fragments. Total bacterial DNA is isolated from Agrobacterium tumefaciens strain C58 mutants that carry a transposon in their Ti-plasmid, and digested with an appropriate restriction endonuclease. The fragments are separated on an agarose gel, denatured and transferred to nitrocellulose filters. These are hybridized against purified wild type pTiC58, or against segments of PTiC58, cloned in E. coli using pBR322 as a vector plasmid. DNA sequences homologous to the probe are detected by autoradiography, thus generating a restriction enzyme pattern of the plasmid from a digest of total bacterial DNA. Mutant fragments can be readily identified by their different position compared to a wild type reference. This protocol eliminates the need to separate the large plasmid from chromosomal DNA for every mutant. In principle, it can be applied to the restriction enzyme analysis of insertion or deletion mutants in any plasmid that has no extensive homology with the chromosome.     

Cloning and mapping of the manganese superoxide dismutase gene (sodA) of Escherichia coli K-12.

An Escherichia coli gene bank composed of large DNA fragments (about 40 kilobases) was constructed by using the small cosmid pHC79. From it, a clone was isolated for its ability to overproduce superoxide dismutase. The enzyme overproduced was manganese superoxide dismutase, as determined by electrophoresis and antibody precipitation. Maxicell analysis and two-dimensional O'Farrell polyacrylamide gel electrophoresis demonstrated that the structural gene, sodA, of manganese superoxide dismutase was cloned. Subcloning fragments from the original cosmid located the sodA gene within a 4.8-kilobase EcoRI-BamHI fragment. This fragment was inserted into a lambda phage which was deleted for the att region and consequently could only lysogenize by recombination between the cloned bacterial DNA insertion and the bacterial chromosome. Genetic mapping of the prophage in such lysogens indicated that the chromosomal sodA locus lies near 87 min on the E. coli map.     

Cloning the cyd gene locus coding for the cytochrome d complex of Escherichia coli

Two plasmids containing the two structural genes for the inner-membrane-bound cytochrome d complex (Cyd) have been isolated from the Clarke and Carbon Escherichia coli DNA bank. A 5.4-kb DNA fragment from one plasmid was subcloned in both orientations into pBR322. The promoter(s) and both genes must have been present within this fragment since the two orientations yielded similar levels of Cyd. Recombination and transduction studies indicated that the cyd gene locus had been isolated. These results demonstrate that cyd contains all the structural information for the complex. Overproduction of Cyd has yielded a visual screening procedure for plasmids bearing cyd that is unique to colored proteins like cytochromes. Colonies of E. coli bearing the cloned cyd gene are yellow-green. The cyd gene can, therefore, be used as a vehicle for detection of inserted DNA fragments.     

An E. coli promoter that is sensitive to visible light

It has been discovered that expression of promoter activity can be inhibited by visible light when specific fragments of E. coli DNA are inserted in a vector system designed to assay for promoter activity. These fragments have been located on regions of the E. coli chromosome to which no gene has been assigned to date. The effective wavelength of light that produces this phenomenon has been determined.     

Cloning and expression in Escherichia coli and Bacillus subtilis of the hemolysin (cereolysin) determinant from Bacillus cereus.

From a cosmid gene bank of Bacillus cereus GP4 in Escherichia coli we isolated clones which, after several days of incubation, formed hemolysis zones on erythrocyte agar plates. These clones contained recombinant cosmids with B. cereus DNA insertions of varying lengths which shared some common restriction fragments. The smallest insertion was recloned as a PstI fragment into pJKK3-1, a shuttle vector which replicates in Bacillus subtilis and E. coli. When this recombinant plasmid (pJKK3-1 hly-1) was transformed into E. coli, it caused hemolysis on erythrocyte agar plates, but in liquid assays no external or internal hemolytic activity could be detected with the E. coli transformants. B. subtilis carrying the same plasmid exhibited hemolytic activity at levels comparable to those of the B. cereus donor strain. The hemolysin produced in B. subtilis seemed to be indistinguishable from cereolysin in its sensitivity to cholesterol, activation by dithiothreitol, and inactivation by antibodies raised against cereolysin. When the recombinant DNA carrying the cereolysin gene was used as a probe in hybridization experiments with chromosomal DNA from a streptolysin O-producing strain of Streptococcus pyogenes or from listeriolysin-producing strains of Listeria monocytogenes, no positive hybridization signals were obtained. These data suggest that the genes for these three SH-activated cytolysins do not have extended sequence homology.