Development of efficient suicide mechanisms for biological containment of bacteria.

To optimize plasmid containment, we have systematically investigated the factors that limit the killing efficiency of a suicide system based on the relF gene from Escherichia coli controlled by inducible lac promoters and placed on plasmids. In induction experiments with this suicide system, killing efficiency was unaffected by temperature and growth medium; there was no requirement for great promoter strength or high plasmid copy number. We could demonstrate that the factors limiting killing were the mutation rate of the suicide function and the reduced growth rate caused by a basal level of expression of the suicide gene during normal growth, which can give a selective growth advantage to cells with mutated suicide functions. The capacity of the plasmid-carried killing system to contain the plasmid was tested in transformation, transduction, and conjugational mobilization. The rate of plasmid transfer detected in these experiments seemed too high to provide adequate biological containment. As expected from the induction experiments, plasmids that escaped containment in these transfer experiments turned out to be mutated in the suicide function. With lac-induced suicide as a test, the efficiency of the system was improved by tightening the repression of the suicide gene, thereby preventing selection of cells mutated in the killing function. Reduction of the mutational inactivation rate of the suicide system by duplication of the suicide function augmented the efficiency of the suicide dramatically. These results permit the construction of extremely efficient biological containment systems.     

Development of efficient suicide mechanisms for biological containment of bacteria

To optimize plasmid containment, we have systematically investigated the factors that limit the killing efficiency of a suicide system based on the relF gene from Escherichia coli controlled by inducible lac promoters and placed on plasmids. In induction experiments with this suicide system, killing efficiency was unaffected by temperature and growth medium; there was no requirement for great promoter strength or high plasmid copy number. We could demonstrate that the factors limiting killing were the mutation rate of the suicide function and the reduced growth rate caused by a basal level of expression of the suicide gene during normal growth, which can give a selective growth advantage to cells with mutated suicide functions. The capacity of the plasmid-carried killing system to contain the plasmid was tested in transformation, transduction, and conjugational mobilization. The rate of plasmid transfer detected in these experiments seemed too high to provide adequate biological containment. As expected from the induction experiments, plasmids that escaped containment in these transfer experiments turned out to be mutated in the suicide function. With lac-induced suicide as a test, the efficiency of the system was improved by tightening the repression of the suicide gene, thereby preventing selection of cells mutated in the killing function. Reduction of the mutational inactivation rate of the suicide system by duplication of the suicide function augmented the efficiency of the suicide dramatically. These results permit the construction of extremely efficient biological containment systems.     

Use of Colicin E3 for Biological Containment of Microorganisms

The genetic determinant of the lethal antibiotic colicin E3 was cloned under the control of a tightly regulated promoter in the absence of the gene for its cognate inhibitor. Combination of this killing cassette with a stringent regulatory element provided a substrate-dependent conditional suicide system that was exploited for the biological containment of a Pseudomonas putida strain. The lethality of a single gene copy and the distinct and universal cellular target of the antibiotic suggest colicin E3 as an ideal candidate for combination with other lethal functions to design highly efficient containment systems for microorganisms.     

A substrate-dependent biological containment system for Pseudomonas putida based on the Escherichia coli gef gene.

A model substrate-dependent suicide system to biologically contain Pseudomonas putida KT2440 is reported. The system consists of two elements. One element carries a fusion between a synthetic lac promoter (PA1-04/03) and the gef gene, which encodes a killing function. This element is contained within a transposaseless mini-Tn5 transposon so that it can be integrated at random locations on the Pseudomonas chromosome. The second element, harbored by plasmid pCC102, is designed to control the first and bears a fusion between the promoter of the P. putida TOL plasmid-encoded meta-cleavage pathway operon (Pm) and the lacI gene, encoding the Lac repressor, plus xylS2, coding for a positive regulator of Pm. In liquid culture under optimal growth conditions and in sterile and nonsterile soil microcosms, P. putida KT2440 (pWWO) bearing the containment system behaves as designed. In the presence of a XylS effector, such as m-methylbenzoate, the LacI protein is synthesized, preventing the expression of the killing function. In the absence of effectors, expression of the PA1-04/03::gef cassette is no longer prevented and a high rate of cell killing is observed. Fluctuation test analyses revealed that mutants resistant to cell killing arise at a frequency of around 10(-5) to 10(-6) per cell per generation. Mutations are linked to the killing element rather than to the regulatory one. In bacteria bearing two copies of the killing cassette, the rate of appearance of mutants resistant to killing decreased to as low as 10(-8) per cell per generation.     

Overproduction of biologically-active human nerve growth factor in Escherichia coli.

A gene coding for human nerve growth factor (hNGF) was constructed for expression under control of the trp promoter in E. coli. The plasmid pTRSNGF contained a synthetic hNGF gene fused, in frame, to the region encoding the beta-lactamase signal peptide. The plasmid pTRLNGF contained the same coding sequence as hNGF attached downstream from the N-terminal fragment of the trp L gene. E. coli cells harboring pTRSNGF produced an amount of hNGF constituting 4% of the total cellular protein, and removed the beta-lactamase signal peptide. The mature protein hNGF was biologically active in the PC12h bioassay for neurite outgrowth. This biological activity was comparable to that of authentic mouse NGF. E. coli cells harboring pTRLNGF produced an amount of fusion protein hNGF constituting 25% of the total cellular protein. Although the fusion protein hNGF formed inclusion bodies in cells, dissolved fusion protein hNGF was active in neurite outgrowth from PC12h cells.     

A triggered-suicide system designed as a defense against bacteriophages.

A novel bacteriophage protection system for Lactococcus lactis based on a genetic trap, in which a strictly phage-inducible promoter isolated from the lytic phage phi31 is used to activate a bacterial suicide system after infection, was developed. The lethal gene of the suicide system consists of the three-gene restriction cassette LlaIR+, which is lethal across a wide range of gram-positive bacteria. The phage-inducible trigger promoter (phi31P) and the LlaIR+ restriction cassette were cloned in Escherichia coli on a high-copy-number replicon to generate pTRK414H. Restriction activity was not apparent in E. coli or L. lactis prior to phage infection. In phage challenges of L. lactis(pTRK414H) with phi31, the efficiency of plaquing was lowered to 10(-4) and accompanied by a fourfold reduction in burst size. Center-of-infection assays revealed that only 15% of infected cells released progeny phage. In addition to phage phi31, the phi31P/LlaIR+ suicide cassette also inhibited four phi31-derived recombinant phages at levels at least 10-fold greater than that of phi31. The phi31P/LlaIR+-based suicide system is a genetically engineered form of abortive infection that traps and eliminates phages potentially evolving in fermentation environments by destroying the phage genome and killing the propagation host. This type of phage-triggered suicide system could be designed for any bacterium-phage combination, given a universal lethal gene and an inducible promoter which is triggered by the infecting bacteriophage.     

Efficient generation of recombinant adenovirus vectors by homologous recombination in Escherichia coli.

Despite recent technical improvements, the construction of recombinant adenovirus vectors remains a time-consuming procedure which requires extensive manipulations of the viral genome in both Escherichia coli and eukaryotic cells. This report describes a novel system based on the cloning and manipulation of the full-length adenovirus genome as a stable plasmid in E. coli, by using the bacterial homologous recombination machinery. The efficiency and flexibility of the method are illustrated by the cloning of the wild-type adenovirus type 5 genome, the insertion of a constitutive promoter upstream from the E3 region, the replacement of the E1 region by an exogenous expression cassette, and the deletion of the E1 region. All recombinant viral DNAS were shown to be fully infectious in permissive cells, and the modified E3 region or the inserted foreign gene was correctly expressed in the infected cells.     

A phagemid vector using the E. coli phage shock promoter facilitates phage display of toxic proteins

Phage display is a powerful tool with which to adapt the specificity of protease inhibitors. To this end, a library of variants of the potato protease inhibitor PI2 was introduced in a canonical phagemid vector. Although PI2 is a natural trypsin inhibitor, we were unable to select trypsin-binding variants from the library. Instead, only mutants carrying deletions or amber stop codons were found. Bacteria carrying these mutations had a much faster growth rate than those carrying the wt PI2-encoding gene, even when the promoter was repressed. To overcome these problems, two new phagemid vectors for g3-mediated phage display were constructed. The first vector has a lower plasmid copy number, as compared to the canonical vector. Bacteria harboring this new vector are much less affected by the presence of the PI2-g3 fusion gene, which appears from a markedly reduced growth retardation. A second vector was equipped with the promoter of the Escherichia coli psp operon, instead of the lac promoter, to control the PI2-g3 gene fusion expression. The psp promoter is induced upon helper phage infection. A phagemid vector with this promoter controlling a PI2-g3 gene fusion did not affect the viability of the host. Furthermore, both new vectors were shown to produce phage particles that display the inhibitor protein and were therefore considered suitable for phage display. The inhibitor library was introduced in both new vectors. Trypsin-binding phages with inhibitory sequences were selected, instead of sequences with stop codons or deletions. This demonstrates the usefulness of these new vectors for phage display of proteins that affect the viability of E. coli.     

Conditional suicide system of Escherichia coli released into soil that uses the Bacillus subtilis sacB gene.

The sacB gene from Bacillus subtilis confers sucrose sensitivity upon gram-negative bacteria. The gene was investigated for use as a potential conditional suicide system for Escherichia coli released into soil. To ensure against the loss of the cell death function encoded under nonselective conditions, the nptI-sacR-B suicide cassette was inserted into the E. coli chromosome by using a circular nonreplicative integration vector. Stability studies yielded no loss of the suicide cassette in the integrated E. coli EL1026 strain. sacB induction in the absence of a selective pressure resulted in a lysis efficiency of up to 99.9%. The microcosm experiments confirmed the ability of the suicide cassette to limit the growth and reduce the survival of E. coli strains released into soil. Sucrose addition to sterile soil resulted in a 10(-3)-fold reduction of the final E. coli population density. sacB induction prevented the proliferation and triggered the rapid disappearance of E. coli from natural soil. Mutation to sucrose tolerance occurred at a frequency of 10(-5), making E. coli EL1026 a potential counterselectable donor strain for gene transfer studies. Specificity and potential adaptability to a wide range of gram-negative bacteria are additional conveniences of this conditional suicide system for the containment and counterselection of engineered microorganisms.     

A novel shuttle vector for Streptomyces spp. and Escherichia coli as a tool in site-directed mutagenesis.

This paper describes the construction and utilization of a novel shuttle vector for Streptomyces spp. and Escherichia coli as a useful vector in site-directed mutagenesis. The shuttle vector pIAFS20 (6.7 kb) has the following features: a replicon for Streptomyces spp., isolated from plasmid pIJ702; the thiostrepton-resistance gene as a selective marker in Streptomyces; the ColE1 origin, allowing replication in E. coli; and the ampicillin-resistance gene as a selective marker in E. coli. Vector pIAFS20 also contains the phage f1 intergenic region, which permits production of single-stranded DNA in E. coli after superinfection with helper phage M13K07. Moreover, the lac promoter is located in front of the multiple cloning sites cassette, allowing eventual expression of the cloned genes in E. coli. After mutagenesis and screening of the mutants in E. coli, the plasmids can be readily used to transform Streptomyces spp. As a demonstration, a 3.2-kb DNA fragment containing the gene encoding the xylanase A from Streptomyces lividans 1326 was inserted into pIAFS20, and the promoter region of this gene served as a target for site-directed mutagenesis. The two deletions reported here confirm the efficiency of this new vector as a tool in mutagenesis.     

Control of gene expression in plant cells using a 434:VP16 chimeric protein

The herpes simplex virus type 1 VP16 polypeptide is a potent trans-activator of viral gene expression. We have tested the ability of the VP16 activation domain to activate gene expression in plant cells. A plasmid encoding a translational fusion between the full-length 434 repressor and the C-terminal 80 amino acids of VP16, was constructed. When expressed in Escherichia coli, the chimeric protein binds efficiently to 434-binding motifs (operators). For expression in plant cells, the chimeric activator gene was placed between the cauliflower mosaic virus (CaMV) 35S promoter and nos terminator sequences in a pUC-based plasmid. The 434 operators were placed upstream of a minimal CaMV 35S promoter linked to the E. coli gus reporter gene. This reporter-expression cassette was then incorporated into the same plasmid as the 434 cI/VP16 activator-expression cassette. Two control plasmids were also constructed, one encoding the 434 protein with no activator domain and the second a chimeric activator with no DNA-binding domain. The chimeric activator was tested for its ability to activate gene expression in a tobacco protoplast transient assay system. Results are presented to show that we can obtain in plant cells significant activation of gene expression that is dependent on both DNA-binding and the presence of the activator domain.     

Expression of a bacterial gene for guanine synthesis inserted into colicin E1 factor by an in vitro recombination.

Regulation of expression of a bacterial guaA gene inserted into colicin E1 DNA by an in vitro recombination was studied under various growth conditions. In Escherichia coli K-12 cells that carried this hybrid ColEl plasmid the level of guaA enzyme activity was not regulated by the concentration of guanine in the medium, but by the number of plasmid DNA copies. The optimal conditions for amplifying the guaA gene product by chloramphenicol treatment were determined. The level of guaA enzyme activity found under the optimal conditions was about 37 times that in extracts of wild-type E. coli cultured in guanine-free medium. The properties of the promoter for the guaA gene and applicability of this hybrid ColEl plasmid for amplification of various gene products were discussed.     

The mdoA locus of Escherichia coli consists of an operon under osmotic control

In Escherichia coli, the 5 kb mdoA locus is involved in the osmotically controlled biosynthesis of periplasmic membrane-derived oligosaccharides (MDOs). The structure of this locus was analysed by in vitro cassette insertion, transposon mutagenesis, and gene-fusion analysis. A 'neo' cassette, derived from the neomycin phosphotransferase II region of transposon Tn5, was inserted into mdoA, borne by a multicopy plasmid. This plasmid was shown to complement two previously described mdoA mutations, depending on the orientation of the exogenous gene. Thus, the gene altered by these mutations could be expressed under the control of the exogenous promoter. Moreover, the 'neo' cassette inactivated another, uncharacterized, mdo gene, because when this insertion was transferred into the chromosome MDO synthesis was abolished. The existence of a second gene was confirmed by complementation analysis with a collection of Tn1000 insertions into mdoA. Two groups were defined, and the two genes are organized into an operon (mdoGH). This conclusion was reached because Tn1000 insertions in the first gene displayed a polar effect on the expression of the second gene. An active gene fusion was obtained on a multicopy plasmid between the beginning of mdoH and lacZ. The hybrid beta-galactosidase activity followed the same osmotically controlled response as that described for of MDO synthesis. This regulation was unaffected by the presence, or absence, of MDOs in the periplasm. Finally, the amount of mdoA-specific mRNAs, determined by dot blot hybridization, decreased when the osmolarity of the growth medium increased.     

Functional expression of human glucose-6-phosphate dehydrogenase in Escherichia coli

The complete coding sequence for human glucose-6-phosphate-dehydrogenase (G6PD) was inserted downstream from the tac promoter of a plasmid, pJF118EH, which also carries the lacIq repressor gene. When Escherichia coli strains (that are unable to grow on glucose due to the absence of functional zwf (G6PD-) and pgi genes) were transformed with this plasmid (pAC1), they were able to grow on glucose as sole carbon source. The rate of growth on glucose was faster in the presence of the inducer of the tac promoter, isopropyl-beta-D-thiogalactopyranoside (IPTG). Extracts of the transformed cells contained a G6PD activity that was not detectable in the parental strains and that was inducible by IPTG. The G6PD activities from normal E. coli and from pAC1-transformed cells comigrated with human G6PD when subjected to electrophoresis on agarose gels. However, when denatured, the G6PD produced by pAC1 was, like the human enzyme, distinguishable from the E. coli-encoded enzyme on the basis of its immunoreactivity with antibody specific for human G6PD. Therefore, human G6PD can be expressed in E. coli and can function to complement the bacterial enzyme deficiency.     

一种新的基于Red重组及I-Sec I体内切割的大肠杆菌基因组无痕删减方法

目前常用的基因修饰方法是在Red同源重组介导下,电转线性PCR片段替换染色体上指定序列。因PCR过程错误掺入,该方法常常会在同源序列部位产生一些突变。为了避免此类突变,我们建立了一种新的无痕删除方法。首先将含有抗性标记(两侧带有I-Sec I识别位点)的线性DNA电转到Red重组感受态细胞内,用抗性基因替换基因组上指定序列;然后,将携带融合同源臂(两侧带有I-Sec I位点)的供体质粒导入上述细胞,诱导表达I-Sec I内切酶切割供体质粒释放同源片段,同时切除染色体上抗性基因产生双链断裂,通过分子间同源重组实现无痕删除。我们应用该方法连续删除了大肠杆菌DH1基因组上11个非必需区,使基因组减小10.59%。PCR测序证明所有删减区域同源臂未发生突变,基因组重测序证明指定区域被删除。删减菌的生长变化不大,但耐酸能力有所改变,并对番茄红素合成有不同影响。