Team:UNICAMP-EMSE Brazil/Results

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===Results===
===Results===
Achieved results indicated that the designed sensor/effector device system was capable of inducible production of GFP (or another generic protein controlled by the sensor). In addition, protein induction can be modulated through varying inducer concentration (Figure 2). Higher concentrations of Paraquat exhibited higher fluorescence levels, which indicates increased GFP concentrations. No plateau was achieved using the highest tested concentrations.  
Achieved results indicated that the designed sensor/effector device system was capable of inducible production of GFP (or another generic protein controlled by the sensor). In addition, protein induction can be modulated through varying inducer concentration (Figure 2). Higher concentrations of Paraquat exhibited higher fluorescence levels, which indicates increased GFP concentrations. No plateau was achieved using the highest tested concentrations.  
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GFP secretion was confirmed by fluorescence emission and estimated to be approximately 10% of total protein, according to fluorescence levels. Significant levels of GFP fluorescence were found only in the supernatant of Paraquat induced cultures containing both the sensor/effector and the secretion systems but not in the non-induced cultures and in the cultures containing only the sensor/effector system (Figure 2).
[[Image:UNICAMP_EMSE_GFP_SOX_device_result1.jpg|center|600px]]
[[Image:UNICAMP_EMSE_GFP_SOX_device_result1.jpg|center|600px]]
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<div align=center>'''Figure 2: SoxS/SoxR fluorescence data (511 nm) for concentrations 0, 5, 10, 20, 30 and 40 µM of inducer.'''</div>
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<div align=center>'''Figure 2: Supernatant fluorescence emission from 508 to 540 nm, excitation in 500 nm. Red line (40 μM Paraquat): sensor/effector with secretion system, showing a clear peak at 511 nm on fluorescence spectrum; Black line (0 μM): non-induced control, sensor/effector with secretion system, non-induced; Blue line (40 µM Paraquat): non-secretion control, sensor/effector without secretion system.'''</div>
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According to the graphic (Fig. 2), the supernatant of the culture harboring the complete secretion system and induced with 40 µM of Paraquat (Red line) exhibited  a well-defined fluorescence peak between 508 and 520 nm, which indicates the presence of GFP in the supernatant probably due to secretion.
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Validating this result, there is no clear fluorescence peak both in the supernatant of non-induced control spectrum (Black line - complete secretion system with 0 µM of Paraquat) and non-secretion control spectrum (Blue line – sensor/effector without secretion system). The aforementioned controls corroborates the result of GFP secretion though the secretion system, eliminating false positive results due to cell lysis for example.
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The experimental concentrations of Paraquat did not show significant differences in cell growth as shown by OD levels in Figure 3.  
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Moreover, we tested if Paraquat could be toxic for the bacteria cells, and we found that the experimental concentrations of Paraquat did not show significant differences in cell growth as shown by OD levels in Figure 3.  
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Additionally, as complementary results for device 2 testing, we used Fluorescence Microscopy to detect the presence of fluorescence in the cultures containing the sensor and GFP production devices when induced with 40 uM of Paraquat against the non-induced cultures. The results also indicated that the bacteria was able to sense NO induced by Paraquat and respond through production of GFP, since microscopy data revealed GFP expression in the Paraquat induced cultures (Figure 5) but not in the non-induced one (Figure 6). This is an additional evidence that the NO sensor system and Sox driven effector synthesis (in this case, GFP) worked as expected.
 
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[[Image:picind.png|center|600px]]
 
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<div align=center>'''Figure 5: GFP fluorescence assessed by microscopy in Paraquat induced cells. A) Fluorescence microscopy 40X Exp.: 0.478 ms; B) Light microscopy 40X; C) Fluorescence microscopy 100X Exp.: 0.478 ms; D) Light microscopy 100X.'''</div>
 
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[[Image:picnotind.png|center|600px]]
 
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<div align=center>'''Figure 6: GFP fluorescence assessed by microscopy in non-induced cells. A) Fluorescence microscopy 40X Exp.: 0.478 ms; B) Light microscopy 40X; C) Fluorescence microscopy 100X Exp.: 0.478 ms; D) Light microscopy 100X.'''</div>
 
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===Discussion===
===Discussion===

Revision as of 02:26, 19 October 2011



Contents

Overview

Functional tests

The students assembled the devices subparts: the SoxR/SoxS sensor (Device 2, NO sensor device/ IL-10 producer), the Adrenaline sensor (Device 1, CA/AI-3 sensor device/ IL-12 producer), and the hemolysin secretion system (Device 3, Protein Secretion System).

The assembled devices related to oxidative-stress sensing ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554010 SoxR transcription factor under control of a strong constitutive promoter - BBa_J23119]) and effector function in response to oxidative stress ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554012 a generic protein fusioned with the C-terminal tail of Hemolysin A - HlyA -under control of the SoxS promoter, recognized by the SoxR transcription factor]) were tested under laboratory conditions using GFP as reporter.


Device 2 testing: SoxR/SoxS system regulating GFP production

The Device 2 is a modification of Stanford team anti-inflammatory device (iGEM 2009 - https://2009.igem.org/Team:Stanford/ProjectPage), which comprises SoxR gene (BBa_K223047) under control of a Constitutive Promoter (BBa_J23119) and SoxS promoter (BBa_K223001 – deleted part), coupled to human IL-10 gene (sequence designed by the team, improved for bacterial expression).

In order to test the ability of Jedi Bacteria in sensing NO levels and activating genes linked to SoxS promoter, we built a Device testing, with GFP linked to SoxS promoter, as it is shown in the following schema (Figure 1):

UNICAMP EMSE GFP SOX device.jpg
Figure 1: Testing Device 2 through replacement of IL-10 to GFP.


Methods

Competent E. coli DH5α strain cells were transformed with a pSB1A2 vector (Ampicillin resistant) carrying both the sensor (Strong_Constitutive_promoter + RBS + SoxR + Terminator) and the effector (SoxS_pormoter + RBS + GFP + HlyA + Terminator) devices using a chemical shock protocol. Transformed bacteria were plated on solid LB medium with 50 μg/mL Ampicillin and grown at 37ºC overnight. Surviving colonies were grown on liquid LB medium containing 50 μg/mL Ampicillin. Oxidative stress was induced by adding increasing concentrations of http://en.wikipedia.org/wiki/Paraquat Paraquat (Methyl viologen dichloride hydrate - Sigma), an oxidative stress inducer in bacteria. Final Paraquat concentrations were: 0 μM (control), 5 μM, 10 μM, 20 μM, 30 μM and 40 μM. Induction of the designed sensor/effector mechanism was accessed by fluorescence using a fluorometer (SLM – Aminco; 4 nm bandpass and 10 mm) with excitation in 500 nm and emission spectra from 508-550 nm. In order to access if increasing concentrations of Paraquat could inhibit culture growth due to it´s toxicity, optical density (OD) levels of the culture were measured during the incubation time with Paraquat. The ability to recognize NO (nitric oxide), an inflammation signal molecule, was characterized for SoxR/SoxS sensor, and found to be FUNCTIONAL. In the section below we present the detailed results.

Results

Achieved results indicated that the designed sensor/effector device system was capable of inducible production of GFP (or another generic protein controlled by the sensor). In addition, protein induction can be modulated through varying inducer concentration (Figure 2). Higher concentrations of Paraquat exhibited higher fluorescence levels, which indicates increased GFP concentrations. No plateau was achieved using the highest tested concentrations.

GFP secretion was confirmed by fluorescence emission and estimated to be approximately 10% of total protein, according to fluorescence levels. Significant levels of GFP fluorescence were found only in the supernatant of Paraquat induced cultures containing both the sensor/effector and the secretion systems but not in the non-induced cultures and in the cultures containing only the sensor/effector system (Figure 2).


UNICAMP EMSE GFP SOX device result1.jpg
Figure 2: Supernatant fluorescence emission from 508 to 540 nm, excitation in 500 nm. Red line (40 μM Paraquat): sensor/effector with secretion system, showing a clear peak at 511 nm on fluorescence spectrum; Black line (0 μM): non-induced control, sensor/effector with secretion system, non-induced; Blue line (40 µM Paraquat): non-secretion control, sensor/effector without secretion system.

According to the graphic (Fig. 2), the supernatant of the culture harboring the complete secretion system and induced with 40 µM of Paraquat (Red line) exhibited a well-defined fluorescence peak between 508 and 520 nm, which indicates the presence of GFP in the supernatant probably due to secretion. Validating this result, there is no clear fluorescence peak both in the supernatant of non-induced control spectrum (Black line - complete secretion system with 0 µM of Paraquat) and non-secretion control spectrum (Blue line – sensor/effector without secretion system). The aforementioned controls corroborates the result of GFP secretion though the secretion system, eliminating false positive results due to cell lysis for example.


Moreover, we tested if Paraquat could be toxic for the bacteria cells, and we found that the experimental concentrations of Paraquat did not show significant differences in cell growth as shown by OD levels in Figure 3.


UNICAMP EMSE GFP SOX device result2.jpg
Figure 3: SoxS/SoxR optical density data for concentrations 0, 5, 10, 20, 30 and 40 µM of inducer.


UNICAMP EMSE GFP SOX device result3.jpg
Figure 4. Determination of specific growth rate (μ) for cells in the control (0 μM) and experimental (40 μM) conditions. X is the cellular concentration per volume. Specific growth rate (μ) is equal to the slope of the plot lnX x time, described by the equation lnX= lnX0 + μt.


Discussion

The SoxR/SoxS system is one of the best characterized redox-sensing mechanisms in bacteria. Under oxidative stress conditions, activation of this system results in a cascade effect that ends in the activation of more than 16 genes that can counteract the harmful effect of superoxide and other oxidative radicals (Pomposiello and Demple 2001).

This device is a modification of Stanford team anti-inflammatory device (iGEM 2009 - https://2009.igem.org/Team:Stanford/ProjectPage), which comprises SoxR gene (BBa_K223047) under control of a Constitutive Promoter (BBa_J23119) and SoxS promoter (BBa_K223001 – deleted part). Although this system has already been designed and used in previously iGEM competitions (iGEM 2009 - https://2009.igem.org/Team:Stanford/ProjectPage), we took advantage of the availability of synthesized sequences to design new parts (SoxR and SoxS) that conforms the common biobrick standards in the iGEM registry. Our team has improved the parts, designing them according to the assembly standard 23, which allows the insertion of more than one coding region in frame. In addition, the new parts are in transcription unit format (with RBS).

These newly designed parts were capable of sensing different concentrations of the inducer, resulting in an increased production of the protein under control of the SoxS promoter (in this case, GFP).

Under the experimental conditions, no cell growth inhibition was observed and confirmed by the calculations of the specific growth rate (μ). No significant difference was found in control experiment (0 μM of Paraquat) and cell induced with 40 μM of Paraquat, both presented μ= 0,18 h-1. Although the Stanford 2009 team showed that Paraquat concentrations between 60 μM and 80 μM can inhibit E. coli cell growth due to enhanced toxicity, but these concentrations were not included in our tests.

With this procedure were able to validate the following parts: SoxS promoter ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554000 BBa_K554000]), SoxR gene ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554003 BBa_K554003]), SoxR device ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554012 BBa_K554012]), SoxS GFP HlyA device [http://partsregistry.org/wiki/index.php?title=Part:BBa_K554012 BBa_K554012]

Device 3 testing, Protein Secretion System

The assembled devices related to secretion system (Hemolysin secretion system under control of SoxS – SoxS-HlyB-HlyD-TolC) were tested under laboratory conditions using GFP as reporter. We were able to validate the parts HlyB ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554007 BBa_K554007]), HlyD ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554008 BBa_K554008]), TolC ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554009 BBa_K554009]), HlyA ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554002 BBa_K554002] and SoxS HlyB HlyD TolC device ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K554013 K554013]).

UNICAMP EMSE secretion device schema2.jpg
Figure 1: Testing Device 3 through replacement of IL-10 to GFP.


Methods

To access GFP secretion, competent E. coli DH5α strain cells were transformed simultaneously with a pSB1C3 vector (Chloramphenicol resistant) carrying both the sensor (Strong_Constitutive_promoter + RBS + SoxR + Terminator) and the effector (SoxS_promoter + RBS + GFP + HlyA + Terminator), and pSB1AK3 (Ampicillin resistant) carrying the secretion system (SoxS_promoter + RBS + HlyB + HlyD + TolC + Terminator). As a non-secretion control, E. coli harboring only the pSB1C3 vector with both sensor and effector systems was used. Oxidative stress was induced by adding [http://en.wikipedia.org/wiki/Paraquat Paraquat] (Methyl viologen dichloride hydrate - Sigma), an oxidative stress inducer in bacteria, according to the following conditions:

  • Sensor/Effector + Secretion system: 0µM Paraquat
  • Sensor/Effector + Secretion system: 40µM Paraquat
  • Sensor/Effector - Secretion system: 40µM Paraquat (non-secretion control)

After 3 hours of induction, samples were collected, centrifuged (4000 rpm / 10 min; to avoid cell lysis) and the supernatant was collected and centrifuged again (13000 rpm / 10 min; to remove remaining cells). The supernatant fluorescence was measured in fluorometer (SLM – Aminco; 4 nm bandpass and 10 mm) with excitation in 500 nm and emission spectra from 508-550 nm. The GFP fluorescence was also detected in cells by fluorescence microscopy (Olympus).

Results

GFP secretion was confirmed by fluorescence emission and estimated to be approximately 10% of total protein, according to fluorescence levels. Significant levels of GFP fluorescence were found only in the supernatant of Paraquat induced cultures containing both the sensor/effector and the secretion systems but not in the non-induced cultures and in the cultures containing only the sensor/effector system (Figure 4).

Unicamp-emse-graph-secr.png
Figure 4: Supernatant fluorescence emission from 508 to 540 nm, excitation in 500 nm. Red line (40 μM Paraquat): sensor/effector with secretion system, showing a clear peak at 511 nm on fluorescence spectrum; Black line (0 μM): non-induced control, sensor/effector with secretion system, non-induced; Blue line (40 µM Paraquat): non-secretion control, sensor/effector without secretion system.

Discussion

This device is a modification of Stanford team 2009 secretion system composite [http://partsregistry.org/Part:BBa_K223062 BBa_K223062]. The secretion system was improved according to biobrick assembly standard 23, and modified by deletion of Hemolysin C (toxin modified enzyme) which is responsible for acylation and activation of HlyA protein (not HlyA secretion signal peptide, used in fusion to GFP, and IL’s). When HlyA protein is activated by HlyC enzyme, is secreted and can cause cytotoxic effects to many cell types. Thus HlyC is related only to pathogenesis and not secretion. This new part was able to secrete GFP fusioned to HlyA secretion peptide signal in response to Paraquat induction of the sensor/effector/secretion system, as showed by supernatant fluorescence.

References

Pomposiell P.J., Demple B. (2001). Redox-operated genetic switches: the SoxR and OxyR transcription factors. Trends in Biotechnology. 19(3):109-114. [http://www.ncbi.nlm.nih.gov/pubmed/11179804 Link to PubMed]



Special acknowledgement:

We would like to thank the following people for the support given in the testing experiments

  • Msc. Viviane Cristina Heinzen da Silva, Laboratório de Bioquímica de Proteínas (LBqP) - IQ/Unicamp
  • Msc. Gleidson Silva Teixeira, Laboratório de Genômica e Expressão (LGE) - IB/Unicamp
  • Dr. Joan Grande Barau, Laboratório de Genômica e Expressão (LGE) - IB/Unicamp