Team:UNAM-Genomics Mexico/Modules/In vivo
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==Tertiary cycle== | ==Tertiary cycle== | ||
- | [[Image:Tertiary-cycle.jpg|thumb|center| | + | [[Image:Tertiary-cycle.jpg|thumb|center|680px| '''Coupling together Biological Chassis through Light communication''' ]] |
===Chassis Description=== | ===Chassis Description=== | ||
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The structure of the device was designed as follows: | The structure of the device was designed as follows: | ||
- | [[Image:LuxAB.jpg|center| | + | [[Image:LuxAB.jpg|center|150px]] |
*Design LuxY biobrick, send to synthesize and transfer the construction from Mr. Gene plasmid to pSB1C3 DNA submission backbone. | *Design LuxY biobrick, send to synthesize and transfer the construction from Mr. Gene plasmid to pSB1C3 DNA submission backbone. | ||
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Luciferase coded by luxA and luxB needs a substrate (an aldehyde synthesized by enzymes into the lux operon), in the project it was decided to add the aldehyde to the reaction in an exogenous way. So the biobrick to synthesize the aldehyde was not designed. | Luciferase coded by luxA and luxB needs a substrate (an aldehyde synthesized by enzymes into the lux operon), in the project it was decided to add the aldehyde to the reaction in an exogenous way. So the biobrick to synthesize the aldehyde was not designed. | ||
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=====METHODOLOGY===== | =====METHODOLOGY===== | ||
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We cotransformated luxABCDE with luxY and the cotransformation was successful although we have not been able to characterize it yet, the experiments are still in process. | We cotransformated luxABCDE with luxY and the cotransformation was successful although we have not been able to characterize it yet, the experiments are still in process. | ||
- | + | ====REFERENCES==== | |
+ | ---- | ||
Thomas O. Baldwin, Mary L. Treat, S. Colette Daubner(1990).Cloning and expression of the luxY gene from Vibrio fischeri strain Y-1 in Escherichia coli and complete amino acid sequence of the yellow fluorescent protein. | Thomas O. Baldwin, Mary L. Treat, S. Colette Daubner(1990).Cloning and expression of the luxY gene from Vibrio fischeri strain Y-1 in Escherichia coli and complete amino acid sequence of the yellow fluorescent protein. | ||
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=====OBJECTIVES===== | =====OBJECTIVES===== | ||
- | *Design and construction of the green | + | *Design and construction of the green light receptor. |
*Expression of accesory genes for PCB creation, Ho1 & pcyA, in order to make the photosensor sensitive to light. | *Expression of accesory genes for PCB creation, Ho1 & pcyA, in order to make the photosensor sensitive to light. | ||
- | *Demonstrate | + | *Demonstrate the Green Receptor activity with a GFP reporter. |
=====METHODOLOGY===== | =====METHODOLOGY===== | ||
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Green reception is composed of a two-component system. The green light sensing agent CcaS, that is a histidine kinase that phosphorylates the transcription factor CcaR, it shows greater affinity for DNA when is phosphorylated. This two-component system has been recently described in Synechocystis sp. PCC 6803, and due to the homology relationship with the EnvZ-OmpR system, it might possibly be functional in E.coli. | Green reception is composed of a two-component system. The green light sensing agent CcaS, that is a histidine kinase that phosphorylates the transcription factor CcaR, it shows greater affinity for DNA when is phosphorylated. This two-component system has been recently described in Synechocystis sp. PCC 6803, and due to the homology relationship with the EnvZ-OmpR system, it might possibly be functional in E.coli. | ||
- | + | Once the sequences of the green light receptor (ccaS),transcriptional factor (ccaR) and DNA regulated region from Synechocystis sp. PCC6803, reported in Yuu Hirose were obtained, they were sent to synthezise. | |
The DNA regulated region by CCaR would be ligated to the GFP protein, to analyze the activity of the photosensor. | The DNA regulated region by CCaR would be ligated to the GFP protein, to analyze the activity of the photosensor. | ||
=====RESULTS===== | =====RESULTS===== | ||
- | Edinburgh team sent us plasmid with accesory genes for PCB creation because we could not get them from the existing biobrick BBa_K098010, which is | + | Edinburgh team sent us plasmid with accesory genes for PCB creation because we could not get them from the existing biobrick BBa_K098010, which is also necessary in the red reception module. |
CcaR and CcaS were ligated to a weak constitutive promoter (J23117). Activity confirmation is still in progress. | CcaR and CcaS were ligated to a weak constitutive promoter (J23117). Activity confirmation is still in progress. | ||
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Lumazine protein of Photobacterium phosphoreum (lumP) is a small protein which shifts the wavelength of light emitted by the P.phosphoreum luciferase LuxAB from 495 nm to about 475 nm. It was used to tune the blue light emission wavelength towards another one closer to that of LovTAP system reception. | Lumazine protein of Photobacterium phosphoreum (lumP) is a small protein which shifts the wavelength of light emitted by the P.phosphoreum luciferase LuxAB from 495 nm to about 475 nm. It was used to tune the blue light emission wavelength towards another one closer to that of LovTAP system reception. | ||
- | + | A version of the lumazine biobrick (BBa_K216007) was sent to us by Edinburgh Team, due to this construction hadn't been tested we decided to synthesize it, in order to avoid unexpected results for possible errors in the already assembled biobrick from Edinburgh. | |
This is the composition of the synthesized sequence, “Gene” stands only for lumazine coding region. | This is the composition of the synthesized sequence, “Gene” stands only for lumazine coding region. | ||
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A second attempt will be using a CCD camera that is expected to have the necessary sensitivity to detect bioluminescence and measure the light emission spectrum. | A second attempt will be using a CCD camera that is expected to have the necessary sensitivity to detect bioluminescence and measure the light emission spectrum. | ||
- | + | ====REFERENCES==== | |
+ | ---- | ||
Yuu Hirose, Takashi Shimada, et al., (2008) Cyanobacteriochrome CcaS is the green light receptor that induces the expression of phycobilisome linker protein. Proceedings of the National Academy of Sciences, 105(28): 9528–9533. | Yuu Hirose, Takashi Shimada, et al., (2008) Cyanobacteriochrome CcaS is the green light receptor that induces the expression of phycobilisome linker protein. Proceedings of the National Academy of Sciences, 105(28): 9528–9533. | ||
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=====OBJECTIVES===== | =====OBJECTIVES===== | ||
- | * | + | *Design and construct an improved version of the LovTAP photosensor under the regulation of different constitutive promoters and with a punctual mutation (ILE427PHE), as was proposed by the model results of the EPF-Lausanne 2009 team. |
- | *Transfer the plasmid with the LovTAP | + | *Transfer the plasmid with the LovTAP synthesized gene from Mr. Gene Plasmid to pSB1C3 DNA submission backbone and ligate the construction to different weak constitutive promoters. |
*Characterize LovTAP reporter systems, both repressor and activator activity. | *Characterize LovTAP reporter systems, both repressor and activator activity. | ||
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The structure of the device is designed as follows: | The structure of the device is designed as follows: | ||
- | [[Image:Promoter%26LovTAP.jpg|center]] | + | [[Image:Promoter%26LovTAP.jpg|150px|center]] |
=====METHODOLOGY===== | =====METHODOLOGY===== | ||
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=====LovTAP design===== | =====LovTAP design===== | ||
+ | The blue light sensor LovTAP biobrick (BBa_K360121) was designed and constructed with some modifications in comparison to the existing LovTAP biobrick (BBa_K191006) available at the registry. It is an improved version that contains a punctual mutation ILE427PHE, which was proposed by the model results of the team EPF-Lausanne 2009, with this mutation LovTAP should react faster and the conformational change should be more stable (the protein stays in the active form for longer, under light induction). | ||
- | + | As well, LovTAP was designed without the inverting regulator sensitive to LacI and CAP protein because according to the report of Lausanne team, the expression levels of LovTAP under the inverting regulator didn’t show differences to the induction with IPTG. Thus, the inverting regulator was removed and none promoter was included in the design that was sent to synthesize, instead several constitutive promoters would be ligatated to the synthesized construction to choose the one that works better. The RBS (ribosome binding site) was changed from a strong to a medium strength. Finally, the 2 PstI restriction sites were removed from the coding region of LovTAP, which makes the LovTAP construction compatible with the 10 standard protocol of biobrick assembly. | |
- | + | So, the LovTAP construction that was sent to synthesize to Mr. Gene Company, consists of the following basic parts: | |
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+ | Prefix+ medium strength RSB + LovTAP Coding sequence + Transcriptional Double Terminator + Suffix | ||
=====E.coli Strain Mutant===== | =====E.coli Strain Mutant===== | ||
- | As | + | As the transcriptional response regulated by LovTAP might also be generated by the trpR repressor in E.coli in tryptophan rich conditions, I looked for an Escherichia coli strain mutant in trpR to avoid the cross-talk of the endogenous function of this gene with LovTAP system. Dr. Charles Yanofsky had the mutant (Identification number: CY15001) and kindly sent it. |
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- | + | According to the sequencing results, the trpR gene from the mutant strain didn’t have a frame shift as is reported at the literature, instead of that it had a non synonymous mutation (Alanine to Proline) corresponding to the aminoacid 80. The hypothesis is that this change might causes a dramatic structural change to the protein thus being non functional. | |
=====LovTAP expression Levels===== | =====LovTAP expression Levels===== | ||
- | + | Dr. Devin Strickland the designer of LovTAP, shared some issues to take into account to work with LovTAP. Analyzing some experimental results reported in his dissertation and in his published paper it is observed that at high expression levels of LovTAP, the behavior in the dark versus the light state is the same. So that, the regulation by light becomes not functional, thus I planned to test LovTAP under three different weak constitutive promoters (J23117, J23114 and J23105) to analyze its behavior and under the strong promoter (J23102), expecting to obtain the behavior reported by Dr. Devin. | |
- | ===== | + | =====LovTAP Reporter systems===== |
- | The | + | The output module of LovTAP is the DNA binding domain of the bacterial transcription factor trp repressor (TrpR), with this domain LovTAP activated can bind as homodimer to the DNA operator called trpL, repressing the transcription. |
- | The | + | The functional elements of the trpL promoter (-35 and -10 boxes, trpR binding sites and transcription start site) were synthesized in an oligonucleotide to introduce it by PCR into a selected plasmid. At the ends the primer includes the prefix and the NheI site that will be used for ligations of the promoter with the reporter systems described later. The primer designed is the following: |
- | + | Primer trpL reverse (5'->3'): NheI site + trpL promoter + Prefix (XbaI + EcoRI sites): | |
- | + | TTGCTAGCGTGAACTTGCGTACTAGTTAACTAGTTCGATGATTAATTGTCAACAGCCTCTAGAAGCGGCCGCGAATTC | |
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- | TTGCTAGCGTGAACTTGCGTACTAGTTAACTAGTTCGATGATTAATTGTCAACAGCCTCTAGAAGCGGCCGCGAATTC | + | |
The primer is the reverse complementary of that sequence so we can use it as a reverse primer, which we used along with a suffix forward to introduce the trpL promoter into pSB1C3 plasmid by PCR. | The primer is the reverse complementary of that sequence so we can use it as a reverse primer, which we used along with a suffix forward to introduce the trpL promoter into pSB1C3 plasmid by PCR. | ||
- | + | Both LovTAP activator and repressor activity were of interest to characterize. So, the following constructions were designed. | |
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*LovTAP repressor activity: Reporter system | *LovTAP repressor activity: Reporter system | ||
- | 1.trpL promoter fused to GFP protein: | + | 1.trpL promoter fused to GFP protein(BBa_E0240): |
[[Image:TrpL_GFP.jpg |center]] | [[Image:TrpL_GFP.jpg |center]] | ||
- | 2.trpL promoter fused to RFP protein: | + | 2.trpL promoter fused to RFP protein(BBa_E1010): |
- | [[Image:TrpL_RFP.jpg|center]] | + | [[Image:TrpL_RFP.jpg|200px|center]] |
*LovTAP activator activity: Reporter system | *LovTAP activator activity: Reporter system | ||
- | trpL promoter fused to lambda Repressor cI | + | trpL promoter fused to lambda Repressor cI (BBa_P0451 + BBa_K098991) regulating GFP protein (BBa_E0240). Whit this system a double repression is generated to have a final activation response. |
- | [[Image:CI.jpg |center]] | + | [[Image:CI.jpg |300px|center]] |
- | ===== | + | =====Characterizing LovTAP===== |
- | Once LovTAP with the three weak constitutive promoters (J23117,123114 and J23105) and strong promoter (J23102) was correctly obtained in plasmid | + | Once LovTAP with the three weak constitutive promoters (J23117,123114 and J23105) and the strong promoter (J23102) was correctly obtained in plasmid pSB3K3, and the reporter system trpL+RFP was also finished in plasmid pSB1C3 , the co-transformation procedure was done, in order to have the whole system inside E.coli cells, both trpR wildtype and mutant. Besides, trpL+RFP construction in plasmid pSB1A2 from Lausanne team was kindly sent it by Edinburgh team. Both trpL-RFP reporter systems were used, being the Lausanne system the reference, expecting to obtain similar results. The difference between the reporter systems is that the constructed in plasmid pSB1C3 doesn’t have the transcriptional double terminator. |
- | In order to test if LovTAP works correctly | + | In order to test if LovTAP works correctly two protocols were implemented: the qualitative and the quantitative approach. |
- | Considerations to take into account: | + | Considerations to take into account: |
+ | |||
+ | *The RFP protein does not include a degradation tag, so the time required to notice a clear difference between light and dark states will be long, because although LovTAP starts to repress, the RFP produced previously by the cells will be still present. | ||
+ | *The plasmid in which LovTAP is being express is pSB3K3 with a copy number around 20 to 30, while trpL-RFP construction is inside plasmids pSB1C3 and pSB1A2; both are high copy number plasmids (100 to 300 per cell). So there are many trpL binding sites that should be repressed by LovTAP. The ideal condition for this experiment would be to have LovTAP and trpL+RFP constructions inside the same plasmid. | ||
+ | *Using the LovTAP constructions fused to promoters with different strength, it can be tested at what levels of expression, the LovTAP light regulation is better. It is already known that under high expression levels of LovTAP, trpL promoter is repressed even in dark. To test this scenario J23102 promoter was used. | ||
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'''Qualitative experiment''' | '''Qualitative experiment''' | ||
- | + | The qualitative approach was designed to observe and compare the RFP production in the cells harboring LovTAP exposed to light versus dark conditions, both in wild type and trpR mutant strains. Under blue light conditions, when LovTAP repressor activity is activated, it is expected to observe a lower level of RFP in comparison to the cells maintained in the dark state. | |
- | + | '''Experimental procedure''' | |
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- | + | The samples used were: trpL+RFP reporter system in plasmid pSB1C3, Lausanne trpL-RFP reporter system, LovTAP under promoters J23117, J23114, J23105 and J23102. | |
- | + | Only one colony of each co-transformation was used along the experiment and was tested under light and dark conditions. | |
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- | + | TrpR mutant and wild type cells were co transformed using 5 µL of each plasmid (trpL-RFP in pSB1C3/ pSB1A2 and each LovTAP construction in pSB3K3). For each co transformation one tube containing 5 ml of LB medium with Kanamicyn and chloramphenicol or Kanamicyn and ampicillin, was inoculated from a single colony of DH5α. Cultures were grown overnight (~15hrs) at 37°C with spinning at 250rpm in dark conditions. Then, 1 ml of broth was taken and transferred into 5 ml of fresh LB medium with antibiotics. The cultures were grown for approximately 13 hours under the previous conditions but some were exposed to blue light (470nm) while others were maintained in dark. Finally, the cultures were spun down and compared as follows: the RFP pellets obtained under blue-light versus dark condition, and wild type samples versus mutant samples. | |
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====Results==== | ====Results==== | ||
- | + | In a first approach was observed that wt and trpR mutant cells co-transformed with LovTAP under J23102 promoter grew in dark and light, produced very low levels of RFP protein in comparison with the control sample (wild type cells with only the reporter construction, trpL+RFP). Besides, there was no a visible difference between dark and light conditions, which is the expected behavior under high expression levels of LovTAP. Considering this result we decided to continue the co-transformations procedure without considering the LovTAP construction under J23102 promoter. | |
- | + | Using LovTAP with promoters J23105, J23114 and J23117 (in order of high to lower strength), we obtained the following pellets that are show in the next images: | |
- | + | [[Image:TrpLWiFiassay.jpg|thumb|center|450 px|'''Testing LovTAP with trpL+RFP reporter system in plasmid pSB1C3'''(without the double transcriptional terminator). The figure shows the pellets obtained from the cellular cultures. The non aligned tube at the right is a sample of WT cells harboring only trpL+RFP construction.]] | |
- | + | [[Image:TrpLassayLaussane.jpg|thumb|center|450px|'''Testing LovTAP with Lausanne trpL+RFP reporter system in plasmid pSB1A2'''. The figure shows the pellets obtained from the cellular cultures. The non aligned tube at the left is a sample of WT cells harboring only trpL+RFP from Lausanne team construction.]] | |
- | + | According to the images trpR mutants seem to have a lower RFP expression levels versus WT both in dark and light conditions. This is a surprising result because it was expected that showed higher levels than WT as they don’t have the possible crass-talk with trpR native E.coli repressor. Maybe there is another process of trpL repression independent to LovTAP and trpR. | |
- | + | Both trpL-RFP reporter systems give similar results. Comparing blue-light versus dark exposed samples there seems to be a small difference visible by naked-eye, with higher levels of RFP protein in dark state samples. Maybe the small difference observed between light and dark conditions is because LovTAP protein levels are very low to considerably repress the trpL promoter. As well, the long half-life of the RFP protein could be masking a significant difference between both states. | |
- | + | Although these results not formally demonstrate that the LovTAP repression is light dependent, it seems that in cells co-transformed with LovTAP versus those transformed only with the trpL-RFP system, there are lower levels of RFP. Another interesting pattern observed in the samples, is that there are lower levels of RFP as the promoter strength that regulates LovTAP increases, thus suggesting that there is a gradient of repression depending on the LovTAP concentration. | |
- | + | These results suggest that possibly LovTAP is working well, however as this experiment is totally qualitative, it must be improved taking into account the optical density of the samples, because the observations could be due to the presence of different number of cells in each sample. As well replicates of the experiment are needed. | |
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- | These results suggest | + | |
'''Quantitative experiment''' | '''Quantitative experiment''' | ||
- | With the aim to have a better characterization of LovTAP, we designed a new protocol considering the methodology describe by Jason R Kelly | + | With the aim to have a better characterization of LovTAP, we designed a new protocol considering the methodology describe by Jason R Kelly, we include some changes that are detailed below. |
We decided to start the protocol under blue light conditions to test the dark state, expecting that in dark exposed samples the RFP levels increase in comparison with those samples that are always under blue light. We did this in order to face better the issue of the long half life of the RFP due to it doesn’t have a degradation tag. | We decided to start the protocol under blue light conditions to test the dark state, expecting that in dark exposed samples the RFP levels increase in comparison with those samples that are always under blue light. We did this in order to face better the issue of the long half life of the RFP due to it doesn’t have a degradation tag. | ||
- | + | '''Experimental procedure''' | |
- | + | The samples used were: trpL+RFP reporter system in plasmid pSB1C3, Lausanne trpL-RFP reporter system, LovTAP under promoters J23117, J23114, J23105 and RFP under J23102. | |
- | + | Only one colony of each co-transformation was used along the experiment and was tested under light and dark conditions. | |
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- | + | TrpR mutant and wild type cells were co transformed using 5 µL of each plasmid (trpL-RFP in pSB1C3/ pSB1A2 and each LovTAP construction in pSB3K3). As controls RFP constitutively expressed under J23102 promoter was used and wild type cells transformed just with trpL-RFP. For each transformation one tube containing 5 ml of LB medium with Kanamicyn and chloramphenicol or Kanamicyn and ampicillin, was inoculated from a single colony of DH5α. Cultures were grown overnight (~14hrs) at 37°C with spinning at 100rpm under blue light (470nm) conditions. Then cultures were diluted 1:1000 into 5ml of fresh LB media with antibiotics. These were grown for approximately 4.5 hours under the previous conditions under blue light (470nm). After this step the OD600 was measured from each culture. Based on this OD measurement, the cultures were diluted to the same OD (0.15) in 5 ml of LB fresh media. Then three 200 µL aliquots from each culture were transferred into a flat-bottomed 96 well plate. Samples were loaded in the plate as is shown in the next picture: | |
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- | Samples were loaded in the plate as is shown in the next picture: | + | |
[[Image:LovTAPplate.jpg|center|500px| Overview of the samples organization for LovTAP characterization with the fluorimeter]] | [[Image:LovTAPplate.jpg|center|500px| Overview of the samples organization for LovTAP characterization with the fluorimeter]] | ||
- | + | An initial measurement of OD600 and fluorescence (530/25 nm excitation filter, 590/35 nm emission filter) by triplicate was done. Using the light emission device to irradiate the incubator, the plate was maintained during 17 hrs at 37°C with spinning at 35rpm inside the incubator but with a mask in the samples selected for the dark conditions. Then, a second measurement of OD600 and fluorescence was done. Initial data with the second measurement were compared. Background absorbance and fluorescence were determined by measuring wells containing only media, and the values obtained were used to normalize the other samples. | |
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====Results==== | ====Results==== | ||
- | + | The average ODs of the wells with only media and antibiotics changed drastically from the initial to the second measurement(km/amp from 0.282 to 0.09, and km/cm 0. to 0.093), dificulting the data analysis. So the data obtained | |
- | initial | + | were inconsistent and even it was intented to analyse them, there was not the expected difference between light and dark conditions. |
====Conclusions==== | ====Conclusions==== | ||
- | According to the aforementioned results, we think that LovTAP could possibly work well. However we have to improve the characterization protocols in order to support with enough evidence this conclusion. | + | According to the aforementioned results, we think that LovTAP could possibly work well. However we have to improve the characterization protocols in order to support with enough evidence this conclusion. As well, more replicates and controls must be included in the experiments. |
We also think that using other reporter system to describe the transcriptional activation activity of LovTAP using a cascade of double repression, might generate better results. So we will test LovTAP behavior with the cI inverter. | We also think that using other reporter system to describe the transcriptional activation activity of LovTAP using a cascade of double repression, might generate better results. So we will test LovTAP behavior with the cI inverter. | ||
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In order to test the functionality of our Minimum Blue Promoter we succesfully ligated it to | In order to test the functionality of our Minimum Blue Promoter we succesfully ligated it to | ||
our Strong RBS BBa_K360031 and the GFP BBa_E0040. | our Strong RBS BBa_K360031 and the GFP BBa_E0040. | ||
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+ | =====Characterizing YcgF/YcgE BLUE RECEPTION SYSTEM===== | ||
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+ | '''Experimental procedure''' | ||
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+ | It is reported that the response of this promoter is weak in comparison to some others standard strong promoters registered in the Registry of Standard Biological Parts. We implemented a protocol for testing the response of our Minimum Blue Light Receptor Promoter (Min-BP) in which we irradiated cells with the construction Min-BP + RBS BBa_K360031 + GFP BBa_E0040 with blue light (470 nm) leds for different times. We also irradiated with green (540 nm) and red (660 nm) light leds to discard any crosstalk of these wavelengths. GFP expression was compared to a reference: J23101 promoter + RBS BBa_K360031 + GFP BBa_E0040. | ||
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+ | We measured GFP expression of our constructions, in order to irradiate the cells with Min- BP + RBS BBa_K360031 + GFP BBa_E0040 we used blue leds and irradiated the cells for 300 minutes, we also measured GFP expression of cells that were incubated in the dark and cells with the constuction J23101 promoter + RBS BBa_K360031 + GFP BBa_E0040. | ||
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+ | For the experiment, cells were incubated overnight in M9 medium with glycerol (0.4%) as carbon source, in the morning OD600 was measured and cells diluted to 0.07 nm. After dilutions, we started irradiation with blue leds. Temperature is a very important factor in the function of the YcgF/YcgE system; it is reported that at 25ºC the ratio between the YcgE repressor and YcgF activator allows a good repression unless there is blue ligh irradiation, so we incubated cells with this promoter at 25ºC. Cells with the constitutive promoter BBa_J23101 were also incubated overnight at 37ºC. | ||
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+ | ====Results==== | ||
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+ | A graph showing GFP expression of our Minimum Blue Promoter compared with a constitutive promoter is shown here: | ||
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+ | [[Image:Blue_promoter_Comparision_with_constitutive_promoter.jpg|250px|center]] | ||
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+ | Next graph shows GFP expression in presence and absence ob blue light: | ||
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+ | [[Image:Bluepromoter_light_vs_dark.jpg|250px|center]] | ||
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+ | According to the graphs we have shown that our Minimum Blue Light Receptor Promoter works as expected but the response is weak compared to a standard, constitutive promoter BBa_J23101. This results are consistent with previously reported data by the K.U. Leuven 2009 Team. | ||
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+ | In order to increase GFP expression in response to blue light, an amplifier could be used. This means to ligate a T7 polymerase downstream the Minimum Blue Promoter and the GFP downstream a T7 promoter. Additionally, we can increment irradiation time and observe response of our blue light-induced promoter. | ||
+ | |||
====Emission module: Red Firefly Luciferase==== | ====Emission module: Red Firefly Luciferase==== | ||
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*The final aim was the construction of the red light emission device, using the promoter region regulated by LovTAP with the red light emitting luciferase coupled to the Luciferin Regenerating Enzyme (LRE). The structure of the device is designed as follows: | *The final aim was the construction of the red light emission device, using the promoter region regulated by LovTAP with the red light emitting luciferase coupled to the Luciferin Regenerating Enzyme (LRE). The structure of the device is designed as follows: | ||
- | [[Image:Red luciferase.jpg]] | + | [[Image:Red luciferase.jpg|350px|center]] |
*Design LRE biobrick and transfer the plasmid with the synthesised gene from Mr. Gene Plasmid to pSB1C3 DNA submission backbone and assemble it to a constitutive promoter. | *Design LRE biobrick and transfer the plasmid with the synthesised gene from Mr. Gene Plasmid to pSB1C3 DNA submission backbone and assemble it to a constitutive promoter. | ||
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Our goal here was to couple both, luciferase and LRE, to be able to make the construction autonomous after the first and single input of luciferin. We sent to synthesize the LRE enzyme. | Our goal here was to couple both, luciferase and LRE, to be able to make the construction autonomous after the first and single input of luciferin. We sent to synthesize the LRE enzyme. | ||
- | For more details see [http://partsregistry.org/wiki/index.php?title=Part:BBa_K360113 LRE | + | For more details see [http://partsregistry.org/wiki/index.php?title=Part:BBa_K360113 LRE (BBa_K360113)] entry at the Registry page. |
+ | |||
+ | ====REFERENCES==== | ||
+ | ---- | ||
+ | Kelly JR, Rubin AJ, Davis JH, Ajo-Franklin CM, Cumbers J, Czar MJ, de Mora K, Glieberman AL, Monie DD, Endy D: Measuring the activity of BioBrick promoters using an in vivo reference standard. J Biol Eng 2009, 3:4. | ||
+ | |||
+ | Yanofsky, C., R.L. Kelley, V. Horn 1984. Repression is relieved before attenuation in the trp operon of Escherichia coli as tryptophan starvation becomes increasingly severe. J.Bacteriol. 158:1018-1024 | ||
+ | |||
+ | Strickland, D., Moffat, K., & Sosnick, T. (2008). Light-activated DNA binding in a designed allosteric protein. Proceedings of the National Academy of Sciences, 105(31), 10709. | ||
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<html> | <html> | ||
</div> | </div> |
Latest revision as of 02:38, 24 November 2010
Coupling together Biological Chassis
In order to enable the light based communication between bacteria, we have designed a tertiary cycle of different bacteria chassis, assembling each module of reception and emission to construct a light-based feedback loop of red-green-blue light, which will make the proof of concept of communication over distance and proper signal decoding.
Tertiary cycle
Chassis Description
iGEM
iGEM is the International Genetically Engineered Machines Competition, held each year at MIT and organized with support of the Parts Registry. See more here.Synthetic Biology
This is defined as attempting to manipulate living objects as if they were man-made machines, specifically in terms of genetic engineering. See more here.Genomics
We are students on the Genomic Sciences program at the Center for Genomic Sciences of the National Autonomous University of Mexico, campus Morelos. See more here.This site is best viewed with a Webkit based Browser (eg: Google's Chrome, Apple's Safari),
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