Two novel bacterial biosensors for detection of nitrate availability in the rhizosphere

The nitrate-regulated promoter of narG in Escherichia coli was fused to promoterless ice nucleation (inaZ) and green fluorescent protein (GFP) reporter genes to yield the nitrate-responsive gene fusions in plasmids pNice and pNgfp, respectively. While the promoter of narG is normally nitrate responsive only under anaerobic conditions, the L28H-fnr gene was provided in trans to enable nitrate-dependent expression of these reporter gene fusions even under aerobic conditions in both E. coli DH5alpha and Enterobacter cloacae EcCT501R. E. cloacae and E. coli cells containing the fusion plasmid pNice exhibited more than 100-fold-higher ice nucleation activity in cultures amended with 10 mM sodium nitrate than in nitrate-free media. The GFP fluorescence of E. cloacae cells harboring pNgfp was uniform at a given concentration of nitrate and increased about 1,000-fold when nitrate increased from 0 to 1 mM. Measurable induction of ice nucleation in E. cloacae EcCT501R harboring pNice occurred at nitrate concentrations of as low as 0.1 microM, while GFP fluorescence was detected in cells harboring pNgfp at about 10 microM. In the rhizosphere of wild oat (Avena fatua), the whole-cell bioreporter E.cloacae(pNgfp) or E. cloacae(pNice) expressed significantly higher GFP fluorescence or ice nucleation activity when the plants were grown in natural soils amended with nitrate than in unamended natural soils. Significantly lower nitrate abundance was detected by the E. cloacae(pNgfp) reporter in the A. fatua rhizosphere compared to in bulk soil, indicating plant competition for nitrate. Ice- and GFP-based bacterial sensors thus are useful for estimating nitrate availability in relevant microbial niches in natural environments.     

Green Fluorescent Protein-based Expression Screening of Membrane Proteins in Escherichia coli

The production of recombinant membrane proteins for structural and functional studies remains technically challenging due to low levels of expression and the inherent instability of many membrane proteins once solubilized in detergents. A protocol is described that combines ligation independent cloning of membrane proteins as GFP fusions with expression in Escherichia coli detected by GFP fluorescence. This enables the construction and expression screening of multiple membrane protein/variants to identify candidates suitable for further investment of time and effort. The GFP reporter is used in a primary screen of expression by visualizing GFP fluorescence following SDS polyacrylamide gel electrophoresis (SDS-PAGE). Membrane proteins that show both a high expression level with minimum degradation as indicated by the absence of free GFP, are selected for a secondary screen. These constructs are scaled and a total membrane fraction prepared and solubilized in four different detergents. Following ultracentrifugation to remove detergent-insoluble material, lysates are analyzed by fluorescence detection size exclusion chromatography (FSEC). Monitoring the size exclusion profile by GFP fluorescence provides information about the mono-dispersity and integrity of the membrane proteins in different detergents. Protein: detergent combinations that elute with a symmetrical peak with little or no free GFP and minimum aggregation are candidates for subsequent purification. Using the above methodology, the heterologous expression in E. coli of SED (shape, elongation, division, and sporulation) proteins from 47 different species of bacteria was analyzed. These proteins typically have ten transmembrane domains and are essential for cell division. The results show that the production of the SEDs orthologues in E. coli was highly variable with respect to the expression levels and integrity of the GFP fusion proteins. The experiment identified a subset for further investigation.     

Phenotypic plasticity of Escherichia coli at initial stage of symbiosis with Dictyostelium discoideum

We observed the change in the physiological state of Escherichia coli cells at the initial stage for establishing a new symbiotic relationship with Dictyostelium discoideum cells. For the physiological state, we monitored green fluorescence intensity due to a green fluorescent protein (GFP) gene integrated into the chromosome by flow cytometry (FCM). On co-cultivation of the two species, a new population of E. coli cells with increased GFP concentration appeared, and when the formation of mucoidal colonies housing the coexisting two species began, most E. coli cells were from the new population. Further experiments suggest that the physiological change is induced by interaction with D. discoideum cells and is reversible, although the processes of the changes in both directions seem to proceed gradually. The observed phenotypic plasticity, together with natural selection under a co-cultivation environment, may be important for leading to the evolution of a new symbiotic system.     

Tandem screening of toxic compounds on GFP-labeled bacteria and cancer cells in microtiter plates

A 96-well fluorescence-based assay has been developed for the rapid screening of potential cytotoxic and bacteriocidal compounds. The assay is based on detection of green fluorescent protein (GFP) in HeLa human carcinoma cells as well as gram negative (Escherichia coli) and gram positive bacteria (Mycobacterium avium). Addition of a toxic compound to the GFP marked cells resulted in the loss of the GFP fluorescence which was readily detected by fluorometry. Thirty-nine distinct naphthoquinone derivatives were screened and several of these compounds were found to be toxic to all cell types. Apart from differences in overall toxicity, two general types of toxic compounds were detected, those that exhibited toxicity to two or all three of the cell types and those that were primarily toxic to the HeLa cells. Our results demonstrate that the parallel screening of both eukaryotic and prokaryotic cells is not only feasible and reproducible but also cost effective.     

Rapid and sensitive detection method of a bacterium by using a GFP reporter phage

A rapid, sensitive, and convenient method for detecting a specific bacterium was developed by using a GFP phage. Here we describe a model system that utilizes the temperate Escherichia coli-restricted bacteriophage lambda, which was genetically modified to express a reporter gene for GFP to identify the colon bacillus E. coli in the specimen. E. coli infected with GFP phage was detected by GFP fluorescence after 4-6 hr of incubation. The results show that a few bacteria in a specimen can be detected under fluorescence microscopy equipped with a sensitive cooled CCD camera. When E. coli and Mycobacterium smegmatis were mixed in a solution containing GFP phage, only E. coli was infected, indicating the specificity of this method. The method has the following advantages: 1) Bacteria from biological samples need not be purified unless they contain fluorescent impurities; 2) The infection of GFP phage to bacteria is specific; 3) The fluorescence of GFP within infected bacteria enables highly sensitive detection; 4) Exogenous substrates and cofactors are not required for fluorescence. Therefore this method is suitable for any phage-bacterium system when bacteria-specific phages are available.     

Two Novel Bacterial Biosensors for Detection of Nitrate Availability in the Rhizosphere

The nitrate-regulated promoter of narG in Escherichia coli was fused to promoterless ice nucleation (inaZ) and green fluorescent protein (GFP) reporter genes to yield the nitrate-responsive gene fusions in plasmids pNice and pNgfp, respectively. While the promoter of narG is normally nitrate responsive only under anaerobic conditions, the L28H-fnr gene was provided in trans to enable nitrate-dependent expression of these reporter gene fusions even under aerobic conditions in both E. coli DH5α and Enterobacter cloacae EcCT501R. E. cloacae and E. coli cells containing the fusion plasmid pNice exhibited more than 100-fold-higher ice nucleation activity in cultures amended with 10 mM sodium nitrate than in nitrate-free media. The GFP fluorescence of E. cloacae cells harboring pNgfp was uniform at a given concentration of nitrate and increased about 1,000-fold when nitrate increased from 0 to 1 mM. Measurable induction of ice nucleation in E. cloacae EcCT501R harboring pNice occurred at nitrate concentrations of as low as 0.1 μM, while GFP fluorescence was detected in cells harboring pNgfp at about 10 μM. In the rhizosphere of wild oat (Avena fatua), the whole-cell bioreporter E.cloacae(pNgfp) or E. cloacae(pNice) expressed significantly higher GFP fluorescence or ice nucleation activity when the plants were grown in natural soils amended with nitrate than in unamended natural soils. Significantly lower nitrate abundance was detected by the E. cloacae(pNgfp) reporter in the A. fatua rhizosphere compared to in bulk soil, indicating plant competition for nitrate. Ice- and GFP-based bacterial sensors thus are useful for estimating nitrate availability in relevant microbial niches in natural environments.     

Productive interaction of chaperones with substrate protein domains allows correct folding of the downstream GFP domain

Green fluorescent protein (GFP) has been used to report protein folding by correlating solubility with fluorescence. In a GFP fusion protein, an upstream aggregation-prone domain can disrupt de novo folding of the GFP domain in Escherichia coli, resulting in a loss of fluorescence. Previously, we showed that prevention of misfolding of the upstream aggregation-prone domain by a coupled folding and binding interaction during protein synthesis restored both GFP fluorescence and solubility. Since molecular chaperones often fold nascent polypeptides through a bind-and-release interaction, the question remains whether the chaperone interaction with the upstream aggregation-prone domain enhances GFP fluorescence. Here, we demonstrate that a significant increase in GFP fluorescence occurred only when appropriate chaperones that recognized the aggregation-prone protein and helped its folding were co-expressed. A possible correlation between GFP fluorescence and the productive folding by chaperones is proposed. This study may provide a general strategy for identifying chaperones specific for difficult-to-fold proteins.     

Characterization of a small cryptic plasmid from endophytic Pantoea agglomerans and its use in the construction of an expression vector

A circular cryptic plasmid named pPAGA (2,734 bp) was isolated from Pantoea agglomerans strain EGE6 (an endophytic bacterial isolate from eucalyptus). Sequence analysis revealed that the plasmid has a G+C content of 51% and contains four potential ORFs, 238(A), 250(B), 131(C), and 129(D) amino acids in length without homology to known proteins. The shuttle vector pLGM1 was constructed by combining the pPAGA plasmid with pGFPmut3.0 (which harbors a gene encoding green fluorescent protein, GFP), and the resulting construct was used to over-express GFP in E. coli and P. agglomerans cells. GFP production was used to monitor the colonization of strain EGE6gfp in various plant tissues by fluorescence microscopy. Analysis of EGE6gfp colonization showed that 14 days after inoculation, the strain occupied the inner tissue of Eucalyptus grandis roots, preferentially colonizing the xylem vessels of the host plants.     

四环素-绿色荧光蛋白融合蛋白的构建及其活性测定

将来源于水母的绿色荧光蛋白基因 (gfp)和来源于E .coli转座子Tn10的四环素阻遏蛋白基因 (tetR)共同构建到E .coli表达载体pET_30a +上 ,获得TetRC_端与GFPN_端融合蛋白。对经诱导表达并纯化后的融合蛋白 (TR∷GFP)进行荧光发射光谱分析表明 ,该融合蛋白保留了GFP的荧光特性 ,即在 395nm激发下 ,可在 5 10nm附近有特征发射峰。在加入四环素后 ,融合蛋白在 395nm激发下 ,在400nm～700nm范围内的发射光谱发生明显变化 ,荧光强度普遍增加 ,且以 510nm处最大发射峰增幅最大 ,由原来 1132增至 2214 ,而四环素对相同浓度的GFP与TetR荧光影响不大 ,结果表明该融合蛋白 ,能感受外界四环素 ,并产生一定的荧光变化。     

Display of green fluorescent protein on Escherichia coli cell surface

In this study, expression of green fluorescence protein (GFP) on the external surface of Escherichia coli was achieved by construction of a fusion protein between Lpp-OmpA hybrid and a GFP variant, GFPmut2. The GFP was fused in frame to the carboxyl-terminus of Lpp-OmpA fusion previously shown to direct various other heterologous proteins to E. coli cell surface. Western blot analysis of membrane fractions identified the Lpp-OmpA-GFP fusion protein with the expected size (43 kDa). Immunofluorescence microscopy, immunoelectron microscopy, protease and extracellular pH sensitivity assays further confirmed that GFP is anchored on the outer membrane. The GFP displayed on the E. coli outer surface retained its fluorescence and was not susceptible to the indigenous outer membrane protease OmpT even though there are two putative OmpT proteolytic sites present in GFP. Optimization of the expression conditions was conducted using fluorometry, eliminating cumbersome immuno-labeling procedures. Surface-displayed GFP could be used in a variety of applications including screening of polypeptide libraries, development of live vaccines, construction of whole cell allosteric biosensors, and signal transduction studies.     

An efficient strategy for high throughput screening of recombinant integral membrane protein expression and stability

Membrane proteins account for about 30% of the genomes sequenced to date and play important roles in a variety of cellular functions. However, determining the three-dimensional structures of membrane proteins continues to pose a major challenge for structural biologists due to difficulties in recombinant expression and purification. We describe here a high throughput pipeline for Escherichia coli based membrane protein expression and purification. A ligation-independent cloning (LIC)-based vector encoding a C-terminal green fluorescence protein (GFP) tag was used for cloning in a high throughput mode. The GFP tag facilitated expression screening in E. coli through both cell culture fluorescence measurements and in-gel fluorescence imaging. Positive candidates from the GFP screening were subsequently sub-cloned into a LIC-based, GFP free vector for further expression and purification. The expressed, C-terminal His-tagged membrane proteins were purified via membrane enrichment and Ni-affinity chromatography. Thermofluor technique was applied to screen optimal buffers and detergents for the purified membrane proteins. This pipeline has been successfully tested for membrane proteins from E. coli and can be potentially expanded to other prokaryotes.     

Export of active green fluorescent protein to the periplasm by the twin-arginine translocase (Tat) pathway in Escherichia coli

The twin-arginine translocation (Tat) system targets cofactor-containing proteins across the Escherichia coli cytoplasmic membrane via distinct signal peptides bearing a twin-arginine motif. In this study, we have analysed the mechanism and capabilities of the E. coli Tat system using green fluorescent protein (GFP) fused to the twin-arginine signal peptide of TMAO reductase (TorA). Fractionation studies and fluorescence measurements demonstrate that GFP is exported to the periplasm where it is fully active. Export is almost totally blocked in tat deletion mutants, indicating that the observed export in wild-type cells occurs predominantly, if not exclusively, by the Tat pathway. Imaging studies reveal a halo of fluorescence in wild-type cells corresponding to the exported periplasmic form; the GFP is distributed uniformly throughout the cytoplasm in a tat mutant. Because previous work has shown GFP to be incapable of folding in the periplasm, we propose that GFP is exported in a fully folded, active state. These data also show for the first time that heterologous proteins can be exported in an active form by the Tat pathway.     

Quantitative export of a reporter protein,GFP, by the twin-arginine translocation pathway in Escherichia coli

The Tat system mediates the transport of folded proteins across the bacterial cytoplasmic membrane. To study the properties of the Escherichia coli Tat-system, we used green fluorescent protein (GFP) fused to the twin-arginine signal peptide of TMAO reductase (TorA). In the presence of arabinose, low levels of this protein rapidly saturate the translocase and cause the accumulation of inactive, membrane-bound TorA-GFP; fluorescence microscopy also showed active TorA-GFP to be distributed throughout the cytoplasm. However, the efficiency of export can be massively increased by alteration of the growth conditions, and further increased by overexpression of the tatABC genes. Under these conditions, the levels of GFP in the periplasm are raised over 20-fold and the export efficiency nears 100%. These results show that the Tat-system is relatively inactive under some growth conditions and the data suggest that the system may be applicable for the larger-scale export of heterologous proteins.     

Engineering green fluorescent protein as a dual functional tag

A hexa-histidine (6 x His) sequence was inserted into a surface loop of the green fluorescent protein (GFP) to develop a dual functional GFP useful for both monitoring and purification of recombinant proteins. Two variants (GFP172 and GFP157), differentiated by the site of insertion of the 6xHis sequence, were developed and compared with a control variant (GFPHis) having the 6xHis sequence at its C-terminus. The variants were produced in Escherichia coli and purified using immobilized metal affinity chromatography (IMAC). The purification efficiencies by IMAC for all variants were found to be comparable. Purified GFP172 and GFP157 variants retained approximately 60% of the fluorescence compared to that of GFPHis. The reduction in the fluorescence intensity associated with GFP172 and GFP157 was attributed to the lower percentage of fluorescent GFP molecules in these variants. Nonetheless, the rates of fluorescence acquisition were found to be similar for all functional variants. Protein misfolding at an elevated temperature (37 degrees C) was found to be less profound for GFP172 than for GFP157. The dual functional properties of GFP172 were tested with maltose binding protein (MBP) as the fusion partner. The MBP-GFP172 fusion protein remained fluorescent and was purified from E. coli lysate as well as from spiked tobacco leaf extracts in a single-step IMAC. For the latter, a recovery yield of approximately 75% was achieved and MBP-GFP172 was found to coelute with a degraded product of the fusion protein at a ratio of about 4:1. The primary advantage of the chimeric GFP tag having an internal hexa-histidine sequence is that such a tag allows maximum flexibility for protein or peptide fusions since both N- and C-terminal ends of the GFP are available for fusion.     

A novel mutant of green fluorescent protein with enhanced sensitivity for microanalysis at 488 nm excitation.

Green fluorescent protein (GFP) has been utilized as a powerful reporter of gene expression and protein localization in cells. We discovered a mutant carrying point mutation S208L from a UV-excitable GFP (F99S/M153T/V163A). It had the enhanced fluorescence intensity. Introduction of the red-shifted mutations (F64L/S65T) to this mutant led to the GFP having the brightest mutants reported which were expressed in Escherichia coli and excited at 488 nm. The relative fluorescence intensities to that of wild-type GFP and GFPuv were increased about 120- and 10-fold, respectively. It was shown that the S208L mutation contributes to both a higher intrinsic brightness of GFP and a higher expression level in E. coli.     

Application of an Escherichia coli green fluorescent protein-based lysine biosensor under nonsterile conditions and autofluorescence background

AIMS: To examine the utility of an Escherichia coli green fluorescent protein (GFP) containing biosensor for quantification of bioavailable lysine in selected feed samples under nonsterile conditions and to estimate the background fluorescence of analyzed feed samples and evaluate the risk of confounding GFP emission from the lysine assay organism. METHODS AND RESULTS: Escherichia coli lysine auxotroph GFP based biosensor was used to determine the percentage of bioavailable lysine in two samples of soybean-, cottonseed-, and meat and bone meal under nonsterile conditions. The fluorescence emitted by GFP was successfully measured using a spectrofluorimeter to monitor bacterial growth response to protein-derived lysine and lysine containing small peptides. The autofluorescence of analyzed feed samples at different concentrations could also be estimated. CONCLUSIONS: When feed protein concentrations are decreased, autofluorescence interference can be avoided. SIGNIFICANCE: The E. coli lysine auxotroph GFP-based biosensor can successfully be used for the determination of bioavailable lysine in these selected animal feed proteins under nonsterile conditions. IMPACT OF THE STUDY: E. coli GFP biosensor for lysine has potential for routine application in animal feeds.     

Development of a monitoring vector for Leuconostoc mesenteroides using the green fluorescent protein gene

The vector pCW5 with plasmid pC7, originally isolated in Lactobacillus paraplantarum C7 derived from kimchi, was constructed using a p32 strong promoter, the pC7 replicon, and green fluorescent protein (GFP) as the reporter. The constructed vector was transformed into E. coli and Leuconostoc mesenteroides, and GFP expression detected using a Western blot analysis. GFP fluorescence was recognized in E. coli and Leuconostoc mesenteroides using a confocal microscope. In addition, GFP fluorescence was also clearly detected in several industrially important lactic acid bacteria (LAB), including Lactobacillus bulgaricus, Lactobacillus paraplantarum, and Lactobacillus plantarum. Thus, pCW5 was shown to be effective for Leuconostoc mesenteroides when using GFP as the reporter, and it can also be used as a broad-host-range vector for other lactic acid bacteria.     

Single-molecule imaging of full protein synthesis by immobilized ribosomes

How folding of proteins is coupled to their synthesis remains poorly understood. Here, we apply single-molecule fluorescence imaging to full protein synthesis in vitro. Ribosomes were specifically immobilized onto glass surfaces and synthesis of green fluorescent protein (GFP) was achieved using modified commercial Protein Synthesis using Recombinant Elements that lacked ribosomes but contained purified factors and enzyme that are required for translation in Escherichia coli. Translation was monitored using a GFP mutant (F64L/S65T/F99S/M153T/V163A) that has a high fluorophore maturation rate and that contained the Secretion Monitor arrest sequence to prevent dissociation from the ribosome. Immobilized ribosomal subunits were labeled with Cy3 and GFP synthesis was measured by colocalization of GFP fluorescence with the ribosome position. The rate of appearance of colocalized ribosome GFP was equivalent to the rates of fluorescence appearance coupled with translation measured in bulk, and the ribosome-polypeptide complexes were stable for hours. The methods presented here are applicable to single-molecule investigation of translational initiation, elongation and cotranslational folding.     

Detection of Escherichia coli with fluorescent labeled phages that have a broad host range to E. coli in sewage water

Escherichia coli is used as an indicator microorganism in public health. The conventional way to detect E. coli requires several days to produce a result, because it requires incubation of cells. Therefore a rapid and sensitive detection method is needed. T4e-/GFP phage, characterized by suppression of lysozyme and fusion of GFP (green fluorescent protein) to its SOC (small outer capsid) protein, was constructed, and it was shown to be able to detect E. coli K12 sensitively within several hours. However, because the host range of T4 phage to E. coli present in sewage water and sea water is narrow, this phage cannot be used to detect E. coli in environmental water. Two phages named IP008 and IP052, which have a broad host range to E. coli present in sewage influent, were screened from sewage influent. Mixture of these two phages produced clear plaques on 50% of E. coli screened from sewage influent. To use these phages as a tool for detection of E. coli, gfp was inserted into gene e, which encodes a lytic enzyme, and thus lytic-activity-suppressed phages were constructed (IP008e-/GFP and IP052e-/GFP). However, the fluorescent intensity of E. coli cells infected with IP008e-/GFP and IP052e-/GFP was not enough for visualization of the cell. Therefore, in addition to the insertion of gfp into gene e, fusion of GFP to SOC of IP008e-/GFP and IP052e-/GFP was conducted to produce IP008e-/2xGFP and IP052e-/2xGFP. E. coli cells infected with IP008e-/2xGFP and IP052e-/2xGFP showed much stronger fluorescence intensity than E. coli cells infected by IP008e-/GFP and IP052e-/GFP. It is anticipated that, using these GFP-labeled phages, a broad range of E. coli present in sewage influent water can be detected rapidly.     

Quantitative analysis of gene expression with an improved green fluorescent protein. p6.

The fast and easy in vivo detection predestines the green fluorescent protein (GFP) for its use as a reporter to quantify promoter activities. We have increased the sensitivity of GFP detection 320-fold compared to the wild-type by constructing gfp+, which contains mutations improving the folding efficiency and the fluorescence yield of GFP+. Twelve expression levels were measured using fusions of the gfp+ and lacZ genes with the tetA promoter in Escherichia coli. The agreement of GFP+ fluorescence with beta-galactosidase activities was excellent, demonstrating that the gfp+ gene can be used to accurately quantify gene expression in vivo. However, expression of the gfp+ gene from the stronger hsp60 promoter revealed that high cellular concentrations of GFP+ caused an inner filter effect reducing the fluorescence by 50%, thus underestimating promoter activity. This effect is probably due to the higher absorbance of cells containing GFP+. Thus promoters with activities differing by about two orders of magnitude can be correctly quantified using the gfp+ gene. Possibilities of using GFP variants beyond this range are discussed.