Team:UNAM-Genomics Mexico/Modules/In vivo

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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.

First Chassis

First Chassis: Red Light reception module coupled to Green Light emitter module.

Reception module: Red Light Photosensor cph8


Emission module: LuxAB luciferase from vibrio fischeri plus YFP protein


Second Chassis

Second Chassis: Green Light reception module coupled to Blue Light emitter module.

Reception module: Blue Light Photosensor LovTAP



Working in this chassis, we decided to use as blue light receptors: LovTAP photosensor and the native blue light inducible promoter from E.coli.


OBJECTIVES
  • Construct an improved version of the LovTAP photosensor device under the regulation of different constitutive promoters, due to the previous version of LovTAP designed by 2009 Lausanne team didn´t have a differential behavior under the inverting regulator sensitive to LacI and CAP protein, their results showed that the expression levels of LovTAP didn’t show differences to the induction with IPTG. As well, we included a punctual mutation to change the ILE427 by a PHE427, as was proposed by the model results of the team iGEM09_EPF-Lausanne. 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).
  • Characterize LovTAP reporter systems, both repressor and activator activity.

The structure of the device is designed as follows:

Promoter&LovTAP.jpg
METHODOLOGY
LovTAP design
E.coli Strain Mutant
LovTAP expression Levels
trpL promoter
LovTAP Reporter systems

Third Chassis

Third Chassis: Blue Light reception module coupled to Red Light emitter module.


Reception module: Blue Light Photosensor LovTAP



Working in this chassis, we decided to use as blue light receptors: LovTAP photosensor and the native blue light inducible promoter from E.coli.


OBJECTIVES
  • Construct an improved version of the LovTAP photosensor device under the regulation of different constitutive promoters, due to the previous version of LovTAP designed by 2009 Lausanne team didn´t have a differential behavior under the inverting regulator sensitive to LacI and CAP protein, their results showed that the expression levels of LovTAP didn’t show differences to the induction with IPTG. As well, we included a punctual mutation to change the ILE427 by a PHE427, as was proposed by the model results of the team iGEM09_EPF-Lausanne. 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).
  • Characterize LovTAP reporter systems, both repressor and activator activity.

The structure of the device is designed as follows:

Promoter&LovTAP.jpg
METHODOLOGY
LovTAP design

We decided to synthesize the LovTAP photosensor that in comparison with the Part:BBa_K191003 that is already at the registry, has the following differences:

1. The 2 PstI restriction sites were removed from the coding region of LovTAP.

2. We included a punctual mutation to change the ILE427 by a PHE427, as was proposed by the model results of the team iGEM09_EPF-Lausanne [2]. With this mutation LovTAP should stay in the active form for longer, under light induction.

For more details visit the LovTAP entry at the registry page.

3. The part does not include a promoter.

4. The RBS was changed from a strong (Part: BBa_B0030) to a medium strength (Part:BBa_B0032).

5. The stop codon tga was changed for two taa.


E.coli Strain Mutant

As the transcriptional response regulated by LovTAP might also be generated by the trpR repressor in E.coli in tryptophan rich conditions , we looked for an Escherichia coli strain mutant in trpR to avoid the cross-talk of the endogenous function of this gene with our system. After a careful look at the literature, we found that Dr. Charles Yanofsky had the mutant, so we sent him an e-mail, asking him to provide us the mutant.

The features of the mutant are:

1.Identification number: CY15001 2.Sex(Hfr,F+,F-,or F'): F-

5 Mutations:

•lamda- (lambda lysogen deletion)

•IN(rrnD-rrnE)1 (Inverts the region between rrnD and rrnE)

•rph-1 (RNase PH )

•tnaA5 (tryptophanase)

•trpR55 (repressor trpR)


LovTAP expression Levels

We got in touch with Dr. Devin Strickland the designer of LovTAP, in order to get some advices. Analyzing some experimental results reported in his dissertation and in the published paper : Light-activated DNA binding in a designed allosteric protein, it seems 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 we planned to test LovTAP under three different weak constitutive promoters (J23117,J23114 and J23105), expecting that it works well.


trpL promoter

The LovTAP system is composed of two modules, the light-sensitive input module is the LOV2 domain of Avena sativa phototropin 1 (AsLOV2). LOV domains absorb light through a flavin cofactor, photochemically form a covalent bond between the chromophore and a cysteine residue in the protein. The output module is the DNA binding domain of the bacterial transcription factor trp repressor (TrpR). So that, LovTAP activated can bind its operator DNA as a homodimer thus repressing transcription.

The DNA operator region where trp repressor binds was annotated wrongly in the 2009 EPF-Lausanne’s wiki as trpO promoter, but when searching for it in RegulonDB a very well annotated Escherichia coli transcriptional regulation data base, we found that the actually region where trp repressor binds is trpL promoter not trpO.

Knowing that we synthesized only trpLp’s functional elements as an oligonucleotide to introduce by PCR into a selected plasmid as follows:

Primer trpL reverse (5'->3'): NheI site + trpL promoter + XbaI site + EcoRI site:

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.

LovTAP Reporter systems

As we are interested in characterize LovTAP activator and repressor activity. We have designed the following constructions.

  • LovTAP repressor activity: Reporter system

1.trpL promoter fused to GFP protein:Part:BBa_E0240

TrpL GFP.jpg


2.trpL promoter fused to RFP protein: Part: BBa_E1010

TrpL RFP.jpg
  • LovTAP activator activity: Reporter system

trpL promoter fused to lambda Repressor cI: Part:BBa_P0451 + Part:BBa_K098991 regulating GFP protein:Part:BBa_E0240.

CI.jpg

Emission module: Red Firefly Luciferase



The red light emitter system that we decided to use is the firefly luciferase, this luciferase usually emits green light but with a punctual mutation we can shift the emission spectrum from green to red.

OBJECTIVES
  • 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:

Red luciferase.jpg

  • To test that the device works as expected.


METHODOLOGY
Mutated Firefly Luciferase

The original intention was to use the Photinus pyralis luciferase biobrick (BBa_I712019) as a base and to increase its efficiency by using the primer BBa_K360114 (as registered) due to previous design notes as referred in the part design section of this briobrick. After achieving this, a punctual mutation S284T (also known as S851T) was induced to change its emission spectrum from green to red by means of a PCR with special primers (which are also referred in the biobrick part design). The biobrick name is BBa_K360115; unfortunately, we were never able to find out why it was not functional.

Click Beetle Luciferase

By the middle of the summer, we decided to try the luciferase from another organism: Click Beetle, specifically the Promega Chroma-Luc™ Reporter Vectors pCBG99-Basic Vector Restriction Sites and the pCBR-Basic Vector Restriction Sites, where the first one has a green emission and the second one red. The intention was to work with these vectors as a means of having a previously-known-to-be functional luciferase, so that once the LRE biobrick was ready, characterization could be feasible. The first step was to extract the coding sequence of the luciferases from these vectors by means of PCR and also to standardize them by adding the prefix and suffix with the following primers:

Forward Click Beetle luciferase

GAATTCGCGGCCGCTTCTAGAGATTAAAGAGGAGAAAATGGTGAAGCGTGAGAAAAAT

Reverse Click Beetle luciferase

CTGCAGCGGCCGCTACTAGTATTATTAACCGCCGGCCTTCT

The second step was to ligate it into the BBa_J61002 plasmid with a J23101 promoter, and to transform it, having as an output several colonies which were then grown overnight to check whether the luciferases showed any brightness. The protocol followed for the assay is mentioned in BBa_K216015 biobrick, in the Experience part. In this first assay, no luminometer was used; so eventhough we added 1μL of 100mM luciferin and waited in the dark room for ~30min taking pictures with a SLR camera with high ISO (~400), for about 30secs to 1 min exposure, nothing was observed. After the initial disappointment, Mariana talked to Cambridge team and they help us ever since then by sending us some of their constructions (BBa_K325909, BBa_K325109, BBa_K325209, and 2 other biobricks).

LRE design

Luciferin Regenerating Enzyme (LRE) was first reported by Gomi, K. and Kajiyama, N. [(2001) Oxyluciferin, a Luminescence Product of Firefly Luciferase, Is Enzymatically Regenerated into Luciferin. The Journal of Biological Chemistry, Vol. 276, No. 39. This enzyme proved to recycle the luciferase product oxyluciferin. 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.



Tertiary cycle

With the previous chassis assembled, the interchange and processing of information go through an activation signaling cascade, that is illustrated in the next image:

Coupling together Biological Chassis through Light communication

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.

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