Team:Peking S/project/wire/harvest

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<center>The modeling parameter of time dependence curve of salicylate system and cin system</center>
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<center>Table 2: The modeling parameter of time dependence curve of salicylate system and cin system</center>
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Chemical Wire Toolbox


Introduction|Harvesting ‘Chemical Wires’ From Nature|Synthesizing Quorum Sensing Inverters|Orthogonal Activating Matrix


Harvesting ‘Chemical Wires’ From Nature


Contents


Introduction

Engineering microbial consortia provides us a vista for expanded genetic networks. However, organization of engineered consortia requires effective cell-cell communication and currently harnessed quorum sensing modules are far from sufficient, giving the engineering of cell-cell communication an emergent priority. An ideal communication system primarily consists of four elements: Production, Perception, Cell sensitivity and Detoxification. Natural quorum sensing systems is advantageous in production ,perception and cell sensitivity. As for detoxification, it wouldn’t be a major problem if the receiver module is sensitive enough, which frequently occurs to natural regulators. Thus, harvesting ‘chemical wires’ from natural systems would be a feasible strategy.


Yet not every system composed of the elements above would give desired performance in engineered consortia. In order to achieve relatively apparent outcome, proper cell sensitivity is required. Also, because long-term monitoring of population behavior remains a challenge, responding time of the signalling system should be kept in a short period. We set our third criterion on the ability to coordinate population members so as to diminish fluctuations in the system.

According to such criteria , we selected two signal generator-receiver systems as the positive regulating members of our 'chemical wire' toolbox. One employs auto-inducer N-(3-hydroxy-7-cis-tetradecenoyl)-L-homoserine lactone (3OH-C14:1-HSL), as the signal molecule (Figure 1). The other system rewired the heterogeneous producing and receiving systems of Salicylate into a synthetic signaling system(molecule illustrated in Figure 2).

Correspondingly we designed experiment verifying the performance of our devices from three aspects, namely dose response, time dependence and coordination.

Cin system

This system was derived from Gram-negative soil bacteria Rhizobium leguminosarum living in symbiotic association with legumes by forming nodules. In this system, cinI, pcin, cinR are core elements. CinI is a LuxI-family synthase, producing 3OH-C14:1-HSL and cinR is a LuxR-type transcriptional regulator responding to the molecules. Pcin will be activated by the binding of CinR -3OH-C14:1-HSL complex.

As one of the widely-used AHL autoinducing luxI/luxR family members, cinI/cinR system meets the four elements quite well.

LM1.png
Figure 1. N-(3-hydroxy-7-cis-tetradecenoyl)-L-homoserine lactone chemical structure

In order to verify our three criteria, we constructed 3OH-C14:1-HSL generator and receiver devices (shown in Figure 2) and experiments detecting dose response, time dependence and coordination of the device were performed.


Cin.png
(A) (B)
LB2cbbb.png

(C)

Figure 2.Schematic of Cin generator-receiver system. (A) CinI generator plasmid. (B) CinR regulated receiver plasmid. (C) Performance of cinI/cinR quorum sensing system.

Salicylate system

Some microorganisms can degrade salicylate and the mechanism has been studied extensively in Pseudomonas putida. Interestingly, there is a bacterium species named Pseudomonas aeruginosa which can synthesize salicylate. These two bacteria strains provide the possibility of constructing an artificial quorum sensing system.


LM3.png
Figure 3. Chemical structure of salicylate



1. Salicylate operon has a broad concentration response curve

We found that salicylate sensor NahR is able to response to salicylate among a wide concentration range. When induced with high concentration of salicylate, for instance, 10^-3M, the gene of interest regulated by pSal promoter will be dramatically expressed, while NahR could still sense salicylate even as low as 10^-6M.


2. Salicylate would not cause huge burden on the cell metabolism

As a chemical wire, salicylate has small molar mass and simple chemical structure. The synthesis pathway of salicylate only involves two genes. As a result, metabolic burden will not be a hurdle when using salicylate as artificial quorum sensing molecules.


3. Salicylate has a unique chemical feature making it more stable

Benzene ring and carboxyl make salicylate more stable than other quorum-sensing small molecules.


In order to characterize the system, generator device and receiver device were transformed into different strains.


PchBA which locates at generator plasmid encodes an isochorismate pyruvate-lyase and an isochorismate synthase derived from Pseudomonas aeruginosa. PchA, an isochorismate synthase, catalyzes the conversion of chorismate to isochorismate. The enzyme PchB, catalyzes the conversion of isochorismate to salicylate.


NahR is a polypeptide which plays an important role in salicylate operon. The polypeptide can exerts its salicylate-dependent activation sal operon by interacting with the promoter sequence in the region of -83 to -45 base pairs before the transcription start site. Binding of the inducer to the central domain of NahR is thought to cause additional interactions of NahR with sequences near the -35 and DNA bending, both of which promote transcriptional activation, therefore, so if there are no salicylate in the liquid nutrient medium, NahR will not binding on the promoter and lead to RNA ploymerase can not work normally, otherwise, transcription will be actived and downstream of the promoter will be transcripted, in our case, GFP will be expressed.



Salicylate System.png
(A) (B)
LM2cbb.png

(C)

Figure 4. Scheme of salicylate system plasmids and mechanism of generator and receiver system. (A) Autoinducer generator plasmid. Core elements are plac promoter, ribosome binding site(RBS) B0034 and autoinducer synthase gene pchA and pchB. (B) Autoinducer receiver system plasmid. This plasmid contains 3 core parts:NahR, salicylate promoter psal and sal activated gfp. (C) mechanism of experiment system. IPTG with the help of lacI could induce the expression of Protein PchA,PchB. Then they synthesize the autoinducer. In receiver system the autoinducer binds to its receiver protein CinR and the complex actived GFP expression.

Results

Salicylate Testing experiment

In order to comfirm the system work or not. We put generator and recevier cultivate together for 3 hours, then centrifuged cells and resuspended them in phosphate buffer solution (PBS)(Figure.5). Experment result testify salicylate system work.

LM5a.JPG

Figure 5. Salicylate verify experiment result. The tube on the left side is control and tubes 2,3,4 on the right contain mix of Salicylate generator and Salicylate recevier.

Dose Response

cin system

First, we induced generator cell with 10-3M IPTG for 16 hours, then centrifuged cells and collect the supernatant. We use this supernatant as original 3OH-C14:1-HSL solution,then we diluted it to 10-7, 5×10-7, 10-6, 5×10-6, 10-5, 6×10-5, 8×10-5, 10-4, 2×10-4, 4×10-4, 7×10-4, 10-3, 3×10-3, 6×10-3, 8×10-3, 10-2 of original solution concentration respectively. Using these diluted supernatants to induce receiver cells (OD600 0.4) at 37℃ for 3 hours, then centrifuged cells and resuspended in PBS. The GFP fluorescence of each culture was obtained using enzyme-labeled assay. The result is shown in figure 6.

LM6.png

Figure 6. Dose Response Curve. Vertical axis RFU/OD represents GFP expression measured through enzyme-labeled assay and the Horizontal axis represent different relative dilution concentration of 3OH-C14:1-HSL. Data was fitted with Hill function.

salicylate system

We cultivate the recevier E.coli until the OD up to 0.4 and add salicylateinto 16 EP tube containing aforementioned E.coli respectively. Different concentration of salicylate solution will be added, that is 10-7 M, 10-6 M, 5×10-6 M, 10-5 M, 2.5×10-5 M, 5×10-5 M, 7.5×10-5 M, 10-4 M, 2.5×10-4 M, 5×10-4 M, 7.5×10-4 M, 10-3 M. Cultivate the cell for 3 hours at 37℃. Then centrifuged cells and resuspended in phosphate buffer solution (PBS). The GFP fluorescence of each culture was obtained using FCM(flow cytometry). The result is shown in figure 7.

LM7b.png

Figure 7. Dose response curve. Horizontal axis represents GFP expression measured by flow cytometry and the vertical axis represen different salicylate concentration. Data was fitted with Hill function.


Table 1: The modeling parameter of dose response curve of salicylate system and cin system
LM8.png
  • Hill function: LMe1.png

Time Dependence

cin system

We induced E.coli with receiver plasmid using supernatant diluted 10-2 times, and measure OD and absorbance of GFP every 15 minutes.


LM9.png

Figure 9. Time response curve of cin receiver system. We measured RFU and OD600 every 15 minutes and experiment performed in 3 hours.

salicylate system

We cultivate the recevier E.coli until its OD up to 0.4. Afterward, add salicylate into the liquid medium and salicylate ultimate concentration is 10-4 M, at last the gfp expression level of different length will be measured by FCM(flow cytometry), delta time is 15 min or 30 min between each sample.


LM10.png

Figure 10. Time response curve of salicylate recevier. Horizontal axis represent time while the vertical axis represent average fluorescence intensity measured by flow cytometry.


Table 2: The modeling parameter of time dependence curve of salicylate system and cin system
LM11.png


  • Fitted function:
    LMe2.png
The Fluorescence intensity X obeys:
LMe3.png
After integration, we get:
LMe4.png

Coordinatiblity

We induced cin and salicylate cell with Dose Response experiment method. We collect the resuspended and measured FITC-A with flow cytometry. Result as Figure 10 shows.


LM12a.pngLM12b.png
(A) (B)


Figure 12. Distribution of Fluorescence Intensity. (A) Cin receiver system cell distribution of GFP fluorescence intensity. (B) salicylate receiver system cell distribution of GFP fluorescence intensity.


Reference

Craig M and Allan D. Co-ordination of quorum-sensing regulation in Rhizobium leguminosarum by induction of an anti-repressor. Molecular Microbiology,81(4),994–100(2011).

Florence W & Allan D.Quorum-sensing in Rhizobium. Antonie van Leeuwenhoek,81,397-407(2002).

Gary SR and J. AD. Quorum-sensing-regulated transcriptional initiation of plasmid transfer and replication genes in Rhizobium leguminosarum biovar viciae. Microbiology,153,2074–2082(2007).

Adam PA, Christopher AV. Environmental signal integration by a modular AND gate J Christopher Anderson. J. Mol. Biol,355,619–627(2006).

Mark AS and Elizabeth FP. Demonstration, Characterization, and Mutational Analysis of NahR Protein Binding to nah and sal Promoters. Journal of Bacteriology,171,837-846(1989).

Mark AS and paul EW. Identification of the nahR Gene Product and Nucleotide Sequences Required for Its Activation of the sal Operon. Journal of Bacteriology,166,9-14(1986).

Jose LR and Carlos AG. Exploitation of prokaryotic expression systems based on the salicylate-dependent control circuit encompassing nahR/Psal::xylS2for biotechnological applications. Bioengineered Bugs,1:4,244-251(2010).

Woon KL, Hae JS. In vitro binding of purified NahR regulatory protein with promoter Psal. Biochimica et Biophysica,1725,247 – 255(2005)


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