Tn5/7-lux: a versatile tool for the identification and capture of promoters in Gram-negative bacteria

Background

The combination of imaging technologies and luciferase-based bioluminescent bacterial reporter strains provide a sensitive and simple non-invasive detection method (photonic bioimaging) for the study of diverse biological processes, as well as efficacy of therapeutic interventions, in live animal models of disease. The engineering of bioluminescent bacteria required for photonic bioimaging is frequently hampered by lack of promoters suitable for strong, yet stable luciferase gene expression.

Results

We devised a novel method for identification of constitutive native promoters in Gram-negative bacteria. The method is based on a Tn5/7 transposon that exploits the unique features of Tn5 (random transposition) and Tn7 (site-specific transposition). The transposons are designed such that Tn5 transposition will allow insertion of a promoter-less bacterial luxCDABE operon downstream of a bacterial gene promoter. Cloning of DNA fragments from luminescent isolates results in a plasmid that replicates in pir⁺ hosts. Sequencing of the lux-chromosomal DNA junctions on the plasmid reveals transposon insertion sites within genes or operons. The plasmid is also a mini-Tn7-lux delivery vector that can be used to introduce the promoter-lux operon fusion into other derivatives of the bacterium of interest in an isogenic fashion. Alternatively, promoter-containing sequences can be PCR-amplified from plasmid or chromosomal DNA and cloned into a series of accompanying mini-Tn7-lux vectors. The mini-Tn5/7-lux and mini-Tn7-lux vectors are equipped with diverse selection markers and thus applicable in numerous Gram-negative bacteria. Various mini-Tn5/7-lux vectors were successfully tested for transposition and promoter identification by imaging in Acinetobacter baumannii, Escherichia coli, and Burkholderia pseudomallei. Strong promoters were captured for lux expression in E. coli and A. baumannii. Some mini-Tn7-lux vectors are also equipped with attB sites for swapping of the lux operon with other reporter genes using Gateway technology.

Conclusions

Although mini-Tn5-lux and mini-Tn7-lux elements have previously been developed and used for bacterial promoter identification and chromosomal insertion of promoter-lux gene fusions, respectively, the newly developed mini-Tn5/7-lux and accompanying accessory plasmids streamline and accelerate the promoter discovery and bioluminescent strain engineering processes. Availability of vectors with diverse selection markers greatly extend the host-range of promoter probe and lux gene fusion vectors.

Electronic supplementary material

The online version of this article (doi:10.1186/s12866-015-0354-3) contains supplementary material, which is available to authorized users.     

A CRISPR/dCas9-assisted system to clone toxic genes in Escherichia coli

BackgroundThe cloning of toxic genes in E. coli requires strict regulation of the target genes' leaky expression. Many methods facilitating successful gene cloning of toxic genes are commonly exploited, but the applicability is severely limited.MethodsA CRISPR/dCas9-assisted system was used to clone toxic genes in E. coli. The plasmid-based and genome-integrated systems were designed in this study. And the green fluorescent protein characterization system was used to test the repression efficiency of the two systems.ResultsWe optimized the plasmid-based CRISPR/dCas9-assisted repression system via testing different sgRNAs targeting the Ptrc promoter and achieved inhibition efficiency up to 64.8%. The genome-integrated system represented 35.9% decreased GFP expression and was successfully employed to cloned four toxic genes from Corynebacterium glutamicum in E. coli.ConclusionsUsing this method, we successfully cloned four C. glutamicum-derived toxic genes that had been failed to clone in conventional ways. The CRISPR/dCas9-assisted gene cloning method was a promising tool to facilitate precise gene cloning of different origins in E. coli.General significanceThis system will be useful for cloning toxic genes from different origins in E. coli, and can accelerate the related research of gene characterization and heterologous expression in the metagenomic era.     

Artificially Constructed Quorum-Sensing Circuits Are Used for Subtle Control of Bacterial Population Density

Vibrio fischeri is a typical quorum-sensing bacterium for which lux box, luxR, and luxI have been identified as the key elements involved in quorum sensing. To decode the quorum-sensing mechanism, an artificially constructed cell–cell communication system has been built. In brief, the system expresses several programmed cell-death BioBricks and quorum-sensing genes driven by the promoters lux pR and P_lacO-1 in Escherichia coli cells. Their transformation and expression was confirmed by gel electrophoresis and sequencing. To evaluate its performance, viable cell numbers at various time periods were investigated. Our results showed that bacteria expressing killer proteins corresponding to ribosome binding site efficiency of 0.07, 0.3, 0.6, or 1.0 successfully sensed each other in a population-dependent manner and communicated with each other to subtly control their population density. This was also validated using a proposed simple mathematical model.     

Microbioluminescent study of the general toxicity and mutagenicity of pollutants

Bacterial bioluminescence was applied to detection of general toxicity (MIT test) and genotoxicity (SOS-lux test) of some chemicals, seawater, and fresh water. The SOS-induced luminescence of E. coli WP2s (cda::luxCDABE) cells was higher than in E. coli C 600 (cda::luxCDABE) at 37°C and pH 6.5. The mutagenic effect of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), mitomycin C, and hydrogen peroxide determined from the induction of E. coli WP2s cell luminescence was detected at lower concentrations than in the assessment of reversion frequencies. General toxicity was demonstrated by using luminescence inhibition for hydrogen peroxide, Zn²⁺, and Cd²⁺ at low concentrations. Regions of the Krasnodar Krai where sea and fresh waters exerted toxic action on luminescence were determined by the microbioluminescent method.     

Plant tissue-specific promoters can drive gene expression in Escherichia coli

Plant transgenesis often requires the use of tissue-specific promoters to drive the transgene expression exclusively in targeted tissues. Although the eukaryotic promoters are expected to stay silent in Escherichia coli, when the promoter-transgene units within the plant transformation vectors are constructed and propagated, some eukaryotic promoters have been reported to be active in prokaryotes. The potential activity of plant promoter in E. coli cells should be considered in cases of expression of proteins that are toxic for host cells, environmental risk assessment or the stability in E. coli of plant vectors for specific Cre/loxP applications. In this study, DNA fragments harbouring four embryo- and/or pollen-specific Arabidopsis thaliana promoters were investigated for their ability to drive heterologous gene expression in E. coli cells. For this, they were fused to gfp:gus reporter genes in the pCAMBIA1304 vector. Although BPROM, bacterial sigma70 promoter recognition program identified several sequences with characteristics similar to bacterial promoters including -10 and -35 sequences in each of tested fragments, the experimental approach showed that only one promoter fragment was able to drive relatively strong- and one promoter fragment relatively weak-GUS expression in E. coli cells. Remaining two tested promoters did not drive any transgene expression in bacteria. Our results also showed that cloning of a shorter plant promoter sequence into vectors containing lacZ α-complementation system can increase the probability of gene expression driven by upstream located lac promoter. This should be considered when cloning of plant expression units, the expression of which is unwanted in E. coli.     

Cloning and maintenance of the housefly sodium channel gene using low copy number vector and two sequential host strains

In spite of the long history of recombinant DNA technology, some genes have not been successfully cloned in Escherichia coli. This is probably due to the toxic effects of the expressed foreign gene product on E. coli. In initial attempts to clone the full-length Vssc1 voltage-sensitive sodium channel α-subunit gene from houseflies, we used one of the most popular vectors and hosts but were unable to retrieve any intact clone. By using two vectors with different copy numbers and two alternate E. coli host strains, we found that the combined use of a low copy number vector (pALTER-1) and an E. coli host strain that suppresses plasmid replication (ABLE-K) is essential to obtain intact full-length Vssc1 clone. However, since the ABLE-K strain was not a suitable host for the long-term maintenance of Vssc1 gene due to its recombination-positive genotype, it was necessary to transfer the Vssc1 plasmid from the primary host to a secondary host with a recombination-minus genotype (Stbl2) to minimize the chances of deletion or rearrangement. We believe that this cloning strategy, with a low copy number vector and the sequential use of two E. coli strains, will be also applicable for the cloning of other toxic genes.     

Strategies for enhancing bioluminescent bacterial sensor performance by promoter region manipulation

Bioluminescent bacterial sensors are based upon the fusion of bacterial bioluminescence (lux) genes, acting as a reporter element, to selected bacterial stress-response gene promoters. Depending upon the nature of the promoter, the resulting constructs react to diverse types of environmental stress, including the presence of toxic chemicals, by dose-dependant light emission. Two bacterial sensors, harbouring sulA::luxCDABE and grpE::luxCDABE fusions, activated by the model chemicals nalidixic acid (NA) and ethanol, respectively, were subjected to molecular manipulations of the promoter region, in order to enhance the intensity and speed of their response and lower their detection thresholds. By manipulating the length of the promoter-containing segment (both promoters), by introducing random or specific mutations in the promoter sequence or by duplicating the promoter sequence (sulA only), major improvements in sensor performance were obtained. Improvements included significantly enhanced sensitivity, earlier response times and an increase in signal intensity. The general approaches described herein may be of general applicability for optimizing bacterial sensor performance, regardless of the sensing or reporting elements employed.     

Organization of the lux genes of photobacterium phosphoreum

The lux genes from Photobacterium phosphoreum (NCMB844) have been cloned into Escherichia coli in a plasmid containing the T7-bacteriophage promoter. By specific expression in vivo under the T7 promoter, five structural genes (luxA-E) coding for the fatty acid reductase and luciferase polypeptides were identified as well as a new gene, designated as luxF, which codes for a 26kDa polypeptide. This new gene is located between luxB and luxE and thus disrupts the structural gene order of luxCDABE found in the Vibrio genus. The luxF gene and the protein it codes for have recently been identified in other Photobacterium species and so appears to be widely distributed within this genus. Nucleotide sequencing of the luxF gene has shown it to code for a protein homologous to the luciferase subunits, coded by the luxA and luxB genes. Although this gene is not necessary for light emission in all luminescent bacteria, it must play an essential role in the biochemistry, physiology, or ecology of the luminescent system in species of the Photobacterium genus.     

Use of protein stability to develop dual luciferase toxicity bioreporter strains

This study presents a simple protocol to measure 2 promoter activities within a single culture when using both Lux and firefly luciferase (FF-Luc) reporters. To demonstrate this, 2 E. coli strains were constructed using 2 compatible plasmids, one harboring a katG::luc fusion gene and the other either a fabA::lux or grpE::lux fusion gene. To differentiate between the FF-Luc and Lux activities within E. coli, we used the instability of the V. fischeri Lux proteins. Basically, it involved a two step assay where (1) without addition of luciferin, only the Lux activity was assayed and (2) with added luciferin and a heat treatment at 42°C, the FF-Luc activity was assayed. This was possible because a shift from 28 to 42°C for 10 min was sufficient to denature/inactivate the Lux proteins to background levels. After treatment, the substrate for FF-Luc was added and the FF-Luc activity could be reliably measured. Using this protocol, it was possible to assay the activities of both bioluminescent reporter proteins and, thus, the relative activity of the different promoters. Subsequent experiments were performed using known inducers of the katG, fabA and grpE promoters where tests were successfully performed with single compound samples as well as samples causing a variety of stresses. These results clearly demonstrated that two promoter activities can be monitored in a single host with this dual-luciferase system.     

Quantitative,Non-Disruptive Monitoring of Transcription in Single Cells with a Broad-Host Range GFP-luxCDABE Dual Reporter System

A dual promoter probe system based on a tandem bi-cistronic GFP-luxCDABE reporter cassette is described and implemented. This system is assembled in two synthetic, modular, broad-host range plasmids based on pBBR1 and RK2 origins of replication, allowing its utilization in an extensive number of gram-negative bacteria. We analyze the performance of this dual cassette in two hosts, Escherichia coli and Pseudomonas putida, by examining the induction properties of the lacI^q-Ptrc expression system in the first host and the Pb promoter of the benzoate degradation pathway in the second host. By quantifying the bioluminescence signal produced through the expression of the lux genes, we explore the dynamic range of induction for the two systems (Ptrc-based and Pb-based) in response to the two inducers. In addition, by quantifying the fluorescence signals produced by GFP expression, we were able to monitor the single-cell expression profile and to explore stochasticity of the same two promoters by flow cytometry. The results provided here demonstrate the power of the dual GFP-luxCDABE cassette as a new, single-step tool to assess promoter properties at both the population and single-cell levels in gram-negative bacteria.     

Transcriptional feedback regulation of efflux protein expression for increased tolerance to and production of n-butanol

Microorganisms can be engineered to produce a variety of biofuels and commodity chemicals. The accumulation of these products, however, is often toxic to the cells and subsequently lowers production yields. Efflux pumps are a natural mechanism for alleviating toxicity through secretion of the product; unfortunately, pump overexpression also often inhibits growth. Tuning expression levels with inducible promoters is time-consuming and the reliance on small-molecule inducers is cost-prohibitive in industry. We design an expression regulation system utilizing a native Escherichia coli stress promoter, P_gntK, to provide negative feedback to regulate transporter expression levels. We test the promoter in the context of the efflux pump AcrB and its butanol-secreting variant, AcrBv2. P_gntK-driven AcrBv2 confers increased tolerance to n-butanol and increased titers of n-butanol in production. Furthermore, the system is responsive to stress from toxic overexpression of other membrane-associated proteins. Our results suggest a use for feedback regulation networks in membrane protein expression.     

5-Methyltryptophan resistance mutations in Escherichia coli K-12. Mutagenic activity of monofunctional alkylating agents including organophosphorus insecticides

The induction of 5-methyltryptophan (5-MT) resistance mutations was assayed as a test system for mutagenic chemicals in Escherichia coli. It is assumed that different premutational alterations in several genes of the Escherichia coli chromosome will lead to 5-MT-resistant mutants. The chemicals used were three monofunctional alkylating agents as reference compounds, namely β-propiolactone (β-PL), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), and methyl methanesulfonate (MMS), which are all mutagenic in the 5-MT system; of the eight organophosphorus insecticides tested, four have definite mutagenic activity (Dichlorvos, Oxydemetonmethyl, Dimethoate, and Bidrin), one is probably mutagenic (Methylparathion) and the remaining three (Parathion, Malathion and Diazinon) do not induce 5-MT resistance mutations in the conditions used here (< 30% survival). The relative mutagenic activity after a treatment time of 60 min is (in decreasing order) MNNG > MMS > Dichlorvos > Oxydemetonmethyl, Dimethoate and Bidrin. The concentration-dependent mutagenic activity of all mutagenic compounds is nearly linear when plotted on a log-log scale (with slopes varying from 1.0 to 1.5) and could be taken as an indication that one premutational reaction will be sufficient for the induction of one 5-MT-resistant mutant.     

A new idea for simple and rapid monitoring of gene expression: requirement of nucleotide sequences encoding an N-terminal HA tag in the T7 promoter-driven expression in E. coli

Mammalian expression vectors are used to overexpress genes of interest in mammalian cells. High temperature requirement protein A1 (HtrA1), used as a specific target, was expressed from the pHA-M-HtrA1 plasmid in HEK293T cells, inducing cell death. Expression of HtrA1 was driven by the pHA-M-HtrA1 mammalian expression vector in E. coli resulting in growth suppression of E. coli in an HtrA1 serine protease-dependent manner. By using various combinations of promoters, target genes and N-terminal tags, the T7 promoter and N-terminal HA tag in the mammalian expression vector were shown to be responsible for expression of target genes in E. coli. Thus the pHA-M-HtrA1 plasmid can be used as a novel, rapid pre-test system for expression and cytotoxicity of the specific target gene in E. coli before assessing its functions in mammalian cells.