Abstract
Characterizing the dynamics of HydHG—a two-component transcriptional regulatory network for exogenous zinc in E. coli—is essential in understanding the biology of these regulatory and signaling pathways. Here, we used a synthetic biology strategy to modify the dynamic characteristics of the HydHG network in two ways. First, a self-activation loop for HydHG network was created under the control of zraP promoter, after which the threshold Zn2+ concentration for the self-activated HydHG network significantly decreased from 200 to 10 μM. Second, the self-activation loop was integrated into the E. coli genome allowing the threshold Zn2+ concentration to be elevated to 500 μM. As the threshold Zn2+ concentration could be modified in both directions, the introduction of a self-activation loop and the entire genomic integration strategy may prove useful for the creation of a two-component bacterial biosensor with varying sensitivities.
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Introduction
The signaling of bacterial two-component systems (TCS) changes transcriptional programs in response to a variety of external factors that affect bacterial growth, including osmolality, temperature, and the concentration of other important extracellular molecules. Each TCS is composed of a membrane-located histidine sensor kinase and a cytoplasmic transcriptional regulator. When activated and autophosphorylated by ATP, the sensor transfers a phosphoryl group to the regulator, thereby increasing the binding between the regulator and DNA and ultimately modulating the expression of certain target genes [1, 2]. However, engineering the dynamic behavior of signal transduction networks like TCS is a challenging topic.
In recent years, a number of biological sensing systems have been constructed for a zinc-sensing purpose [3–7]. In E. coli, some of proteins involved in zinc homeostasis systems have been identified. Among those proteins, HydH and ZntR were found to respond better to zinc, through involvement in transcriptional regulation of zinc homeostasis genes. The ZntA–ZntR system, which is composed of the zinc efflux protein and zinc binding MerR-like transcriptional activator, respectively, detoxifies zinc but these transcriptional regulators are unable to sense zinc in the environment [8, 9]. HydHG, a two-component membrane associated sensor kinase system in E. coli, can sense extracellular zinc [10].
Self-activation loops are regulatory elements found in bacteria, fungi, plants, and archaea that modulate certain variables of gene expression output such as response timing, response level, and genetic noise [11–13]. Accordingly, the introduction of self-activation loops may play a defining role in further understanding of the dynamic behavior of signal transduction networks, a topic that has remained largely unexplored. In order to construct an efficient biosensor, the output signal must be inducible at various concentrations of target molecule. Here, we intend to utilize the HydHG TCS integrated with a self-activation loop as a zinc-sensing biosensor. Since the HydHG system responds preferentially to higher concentration of Zn2+ [10], there remains a limit on using this bacterial TCS. For Zn2+ of low concentrations, the HydHG TCS system is not efficient. In this study, we aim to construct a HydHG-based zinc sensor functional at varying sensitivities by introducing a rational regulatory network. First, the dynamic behavior of the E. coli HydHG TCS was monitored, after which an inducible positive transcriptional self-activation loop network was introduced to induce HydG activation at low concentrations of Zn2+ (Fig. 1). Second, a self-activation loop was integrated into the E. coli genome to decrease the system sensitivity. Via this protocol, three separate types of zinc-sensing bacteria were created with differing threshold Zn2+ concentrations.
Materials and methods
Plasmid construction
All bacterial strains and plasmids used in this study are listed in Table 1. In all cases, E. coli XL1-Blue was used as the host strain for plasmid construction. To create a self-activation loop plasmid, a 237 bp zraP PCR fragment corresponding to the target promoter gene was generated with zraPprt_FSacI and zraPprt_RKpnI primers (Table 2). This particular fragment was then cloned into the pUC19 vector plasmid at the SacI/KpnI site, ultimately resulting in pUZup1 plasmid [14]. The second PCR fragment of the gfp gene coding for green fluorescent protein (GFP) was also amplified from the plasmid PROBE-NT’ [15] with GFPprt_FKpnI and GFPprt_RBamHI primers (Table 2). This gfp gene was then ligated into pUZup1 at the KpnI/BamHI site to create the pZGFP1 plasmid (Table 1). The third PCR fragment of the hydG gene was also amplified from E. coli genomic DNA using HydG_FBamHI and HydG_RXbaI primers (Table 2), then digested with BamHI/XbaI and ligated into the pZGFP1 vector backbone, ultimately producing the pZSAL1 plasmid (Table 1). Both the pZGFP1 and pZSAL1 plasmids were transferred into the E. coli XL1-Blue [16].
Genomic integration
The chloramphenicol resistance gene was inserted upstream of the zraP promoter in the opposite direction to create the pZSAL1-C plasmid (Table 1). A pKD46 plasmid with the bacteriophage red operon (containing the genes exo, beta, and gam) was used to disrupt a gene in the zraP promoter region of the E. coli XL1-Blue chromosome [17]. Recombinant E. coli XL1-Blue harboring pKD46 was cultured at 30 °C, with recombinases induced via the introduction of l-arabinose (1 mM) when cultures were at an optical density at 600 nm (OD600) of 0.4. Electrocompetent cells were also prepared using the standard protocol. A homologous recombination gene was amplified by PCR using ZSAL_F and ZSAL_R primers and the pZSAL1-C plasmid as a template (Table 2). After homologous recombination transfer into the E. coli XL1-Blue, colonies were selected from LB agar plates using the appropriate antibiotic. Successful gene replacement with the antibiotic marker was then verified by PCR.
zraP-promoter-driven GFP expression analysis
Samples from the culture were obtained after 2 h of induction, washed with phosphate-buffered saline (PBS), and re-suspended in PBS supplemented with 0.3 % of agarose. A reflected fluorescence microscope with a 100× objective (Olympus, Japan) was used for cell fluorescence screening.
Dynamic behavior characterization of the pZGFP1, pZSAL1, and Z-SAL E. coli strains.
Unless otherwise stated, Luria–Bertani (LB) media was used as a liquid culture for transcriptional response studies. All bacterial strains were grown in 200-ml Erlenmeyer flasks containing antibiotics (ampicillin 100 mg/L, chloramphenicol 25 mg/L) at 37 °C under constant rotary shaking (225 rpm). For all induction experiments, GFP levels were quantified using a RF-5301PC spectrofluorimeter (Shimadzu, Japan) with an excitation wavelength of 490/10 nm and an emission wavelength of 510/10 nm. E. coli strain harboring the pUC19 plasmid was used as a control to calibrate the instrument prior to all measurements. A UV/vis spectrophotometer (Shimadzu, Japan) was used to measure the optical density (OD) of samples at 600 nm. The specific fluorescence intensity (SFI) was calculated using the raw fluorescence intensity expressed in relative fluorescence units at an optical density of 600 nm. At least three measurements were obtained for each sample.
Results
Engineering bacteria with a self-activation loop
The E. coli HydHG TCS was engineered to respond to different threshold Zn2+ concentrations, with the threshold level reduced via the introduction of a self-activation loop and elevated by genomic integration. To create a self-activation loop, the hydG gene was cloned downstream of the gfp gene and its expression was regulated by a zraP-responsive promoter (Fig. 1b), pZSAL). If phosphorylated HydG induced the zraP promoter, then HydG was expressed in addition to GFP, thereby further activating the zraP promoter. As such, activation of the above network would allow for self-induction, thus further amplify the resulting output signal (Fig. 1a). A feedback activation loop system was then integrated into the E. coli genome using homologous recombination. Using this protocol, three different types of engineered cells were created: cells harboring pZGFP1 (no self-activation network), pZSAL1 (self-activation network) and E. coli Z-SAL (genomic integration network). Notably, these recombinant bacterial strains with self-activation loops behave like normal bacteria until they are exposed to Zn2+. In the presence of Zn2+, the reporter protein synthesis is upregulated and the strains are consequently transformed into fluorescent cell (Fig. 2).
Dynamic behavior monitoring
The two recombinant plasmids and the strain described above were cultured in varying concentrations of Zn2+ (Fig. 3). All the cells were under the control of the zraP promoter, and were activated at different sensitivity according to the Zn2+ concentration. The E. coli (pZGFP1) fluorescence increased in proportion to the Zn2+ concentration between 10 and 1,000 μM. However, the detection sensitivity was not sufficient for concentrations below 10 μM of Zn2+, as only small increases in GFP fluorescence occurred. In comparison to E. coli (pZGFP1), the output fluorescence of the E. coli (pZSAL1) increased 3-fold when exposed to Zn2+ concentrations as low as 10 μM. Accordingly, the bacterial sensitivity to low concentrations of Zn2+ was greatly enhanced by the introduction of a self-activation loop. The fluorescence did not significantly change in response to further increases of Zn2+ concentration (>10 μM), indicating a fluorescence saturation at 10 μM of Zn2+ that may have resulted from a maximum expression capacity of this engineered cell. Given these results, we conclude that the incorporation of a self-activation loop was a successful strategy for the construction of a fine zinc sensing apparatus. With regard to E. coli (pZSAL1), the threshold concentration for fluorescence was increased to 500 μM, indicating a decrease in zinc sensitivity. These data suggest that genomic integration could successfully be employed for zinc-sensing bacteria over a larger range of Zn2+ concentrations.
To quantify the effect of the self-activation loop on the dynamic behavior of zraP expression, time-dependent fluorescence profiles of three strains were characterized (Fig. 4). The fluorescence of E. coli (pZGFP1) increased after 2 h of cultivation, after which it remained at a similar level for the following 6 h. The E. coli (pZSAL1) and E. coli Z-SAL fluorescence continued to increase over time, suggesting signal amplification after the introduction of the self-activation loop. Notably, the fluorescence of the E. coli Z-SAL strain was roughly half that of the E. coli (pZGFP1) strain after 2 h of induction. However, the E. coli Z-SAL fluorescence increased continuously, and ultimately surpassed that of E. coli (pZGFP1) after 8 h of induction. Such data clearly demonstrate that the signal-amplifying self-activation loop functioned as anticipated in vivo.
Discussion
The zinc sensing behavior of HydHG TCS was modified via the introduction of a self-activation loop. After the incorporation of this self-activation loop, the signal was fully activated at 10 μM of Zn2+. In comparison to this low concentration of Zn2+, the previously reported native HydHG TCS network was activated at a higher Zn2+ concentration of 200 μM [10]. We also could reduce the sensitivity of our zinc sensor using E. coli Z-SAL strain, where the sensitivity was reduced by 50-fold since it was activated at 500 μM of Zn2+ concentration. These results indicate that bacterial TCS sensitivity can be engineered via the introduction of synthetic genetic loops.
The strategy herein may also prove promising for the development of biosensors with varied sensitivities. E. coli (pZSAL1) produced a great signal even at 10 μM of Zn2+ concentration, so possibly replacing the present complicated processes for quantifying Zn2+ of low concentration. The E. coli Z-SAL strain may be used as a simple biosensor recognizing the presence of zinc in severely contaminated sites with relatively high concentration of Zn2+. In conclusion, our data demonstrated the feasibility of TCS-based biosensors for the detection of Zn2+ at various concentrations. The strategy also can be applied to optimize the signal transduction kinetics of other TCSs.
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Acknowledgments
This research was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (2010-0012850).
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V. D. Pham and S. Ravikumar contributed equally to this work.
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Pham, V.D., Ravikumar, S., Lee, S.H. et al. Modification of response behavior of zinc sensing HydHG two-component system using a self-activation loop and genomic integration. Bioprocess Biosyst Eng 36, 1185–1190 (2013). https://doi.org/10.1007/s00449-012-0845-7
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DOI: https://doi.org/10.1007/s00449-012-0845-7