Revision as of 18:19, 13 October 2018

Simply

Design

The construct circuit is a positive-feedback amplification circuit where a transcriptional activator activates a promoter leading to transcription of itself and a target gene - thus further promoting formation of itself. This circuit has been shown to work in a robust manner and provide a higher level of gene expression than a circuit without the amplification action. [1] We have added an inducible promoter at the start of the construct to first initiate expression of the transcriptional activator which will initiate the amplification action. This will result in an amplified response of our target gene (phoD) in presence of an inducer - which in our case will be the root exudates of the crops.

Amplification Circuit Design

Description

The designed construct is a positive feedback genetic amplifier which activates when induced by an external chemical moiety (root exudates in this case). P_X is that inducible promoter. TA is the transcription activator which acts as inducer to the promoter P_TA. Promoter PTA_{, when induced, starts the transcription of TA along with a reporter gene rfp. As the transcription of TA is continuous, promoter P_TA is continuously turned on and the response to the inducer is amplified.}

Promoter P_X

P_X is a inducible promoter which is turned on when activated by an external stimulus. Via RNAseq, we wish to isolate the promoters of the genes which are upregulated in Bacillus subtilis 168 in presence of root exudates of various crops. While the results of RNAseq are awaited, a bacitracin-inducible promoter, P_LiaI (Part #BBa_823001) was isolated from the registry and used instead. Experiments were performed to isolate various sugar inducible promoters such as, P_MalA (Maltose inducible), PXylA_{(Xylose inducible), P_MtlA (Mannitol inducible), from the genomic DNA of B. subtilis 168. Constitutive promoters for B. subtilis were isolated from the registry and used instead of inducible promoters to check validity of the construct. For detailed results, see results page.}

Transcription Activator (TA)

The transcription activator is the backbone of the construct as it activates the promoter which in turn starts the transcription of the transcription activator itself. In order to construct the positive feedback amplifier, we required a transcription activator which did not interfere with native gene regulation in either B. subtilis or E. coli and acted as an inducer to another promoter as well.
Two such transcription activators were chosen from iGEM 2018 Distribution Kit.

Pag activator from phage PSP3 (Part #BBa_I746351)
Ogr activator from phage P2 (Part #BBa_I746350)

For detailed results, see results page.

Promoter induced by transcription activator (P_TA)

P_TA is the promoter which, when induced by the transcription activator, drives the transcription of the output reporter gene along with transcription activator itself. The promoters which could be activated by Pag or Ogr activators were required for the construct. Two such promoters were chosen from iGEM 2018 Distribution Kit:

Promoter PF from phage P2 (Part #BBa_I746360)
Promoter PO from phage P2 (Part #BBa_I746361)

As both of these are non-native to the chassis organism, the interference with native gene regulation is not expected.

Reporter Gene

The positive feedback circuits leads to the amplification of response to inducers. For the quantification of this response, the reporter gene rfp was selected as the output for its ease in characterization using measurement of fluorescence and easy availability in iGEM 2018 Distribution Kit.

Please click here for detailed documentation of results.

@@ Line 5: / Line 5: @@
 <h1>Design</h1>
 <p>
-The aim of the project is to identify the promoters that are activated by the exudates of common crops via the root exudates. Applications of this idea are endless, but as a case study, we have designed a amplification circuit which can in turn be used to improve the efficiency of phosphate solubilization in the soil. Our chassis organism is Bacillus subtilis, a common soil bacterium. As this amplification circuit is going to be activated by the root exudates of particular crops, this phosphate solubilization will take place only in the rhizosphere of the crops of interest and not in the fallow land.
+The construct circuit is a positive-feedback amplification circuit where a transcriptional activator activates a promoter leading to transcription of itself and a target gene - thus further promoting formation of itself. This circuit has been shown to work in a robust manner and provide a higher level of gene expression than a circuit without the amplification action. [1]
+We have added an inducible promoter at the start of the construct to first initiate expression of the transcriptional activator which will initiate the amplification action. This will result in an amplified response of our target gene (<i>phoD</i>) in presence of an inducer - which in our case will be the root exudates of the crops.
 </p>
 <h3>Amplification Circuit Design</h3>
@@ Line 13: / Line 14: @@
 <h4>Description</h4>
 <p>
-The construct that we have designed, is theoretically self-sustainable, once activated by the inducer. P<sub>1</sub> is the inducible promoter.  G<sub>1</sub> is a sequence of bases that codes for the activator protein which acts as an inducer to the promoter P<sub>2</sub>. Promoter P<sub>2</sub>, when induced, starts the transcription of  G<sub>1</sub> along with a reporter gene, Red Fluorescent Protein (RFP) in this case. As the transcription of  G<sub>1</sub> is started again, promoter P<sub>2</sub> is continuously turned on, which makes this construct self-sustainable.
+The designed construct is a positive feedback genetic amplifier which activates when induced by an external chemical moiety (root exudates in this case). P<sub>X</sub> is that inducible promoter. TA is the transcription activator which acts as inducer to the promoter P<sub>TA</sub>. Promoter P</sub>TA<sub>, when induced, starts the transcription of TA along with a reporter gene <i>rfp</i>. As the transcription of TA is continuous, promoter P<sub>TA</sub> is continuously turned on and the response to the inducer is amplified.
 </p>
-<h4>Promoter P<sub>1</sub></h4>
+<h4>Promoter P<sub>X</sub></h4>
 <p>
-For experimental purposes, while we have not received the RNA sequencing results, we tried out various inducible promoters for Bacillus subtilis. We were able to get one promoter P<sub>liaI</sub> (Part # BBa_823001) from the iGEM 2018 distribution kit, which is a bacitracin inducible promoter for B subtilis. We were not able to get expected results with it.<br><br>
+P<sub>X</sub> is a inducible promoter which is turned on when activated by an external stimulus. Via RNAseq, we wish to isolate the promoters of the genes which are upregulated in <i>Bacillus subtilis</i> 168 in presence of root exudates of various crops.
-We also tried to PCR amplify a few inducible promoters from the Bacillus subtilis 168 genome, namely:
+While the results of RNAseq are awaited, a bacitracin-inducible promoter, P<sub>LiaI</sub> (Part #BBa_823001) was isolated from the registry and used instead. Experiments were performed to isolate various sugar inducible promoters such as, P<sub>MalA</sub> (Maltose inducible), P</sub>XylA<sub> (Xylose inducible), P<sub>MtlA</sub> (Mannitol inducible), from the genomic DNA of <i>B. subtilis</i> 168. Constitutive promoters for <i>B. subtilis</i> were isolated from the registry and used instead of inducible promoters to check validity of the construct. For detailed results, see results page.
 </p>
+<h4>Transcription Activator (TA)</h4>
+<p>The transcription activator is the backbone of the construct as it activates the promoter which in turn starts the transcription of the transcription activator itself. In order to construct the positive feedback amplifier, we required a transcription activator which did not interfere with native gene regulation in either <i>B. subtilis</i> or <i>E. coli</i> and acted as an inducer to another promoter as well. <br>
+Two such transcription activators were chosen from iGEM 2018 Distribution Kit.</p>
 <ol>
-<li>pMalA: Maltose inducible promoter
+<li>
-<li>pXylA: Xylose inducible promoter
+Pag activator from phage PSP3 (Part #BBa_I746351)
-<li>pMtlA: Mannitol inducible promoter
+<li>
+Ogr activator from phage P2 (Part #BBa_I746350)
 </ol>
-<h4>Gene G<sub>1</sub> and Promoter P<sub>2</sub></h4>
 <p>
-These two parts are the soul of the whole construct as these are the ones which make the circuit self-sustainable. Promoter P<sub>2</sub>, which is induced by the activator protein coded by the gene G<sub>1</sub> again starts the transcription of the same gene G<sub>1</sub>. Hence, when the circuit is activated by the inducible promoter P<sub>1</sub>, transcription of G<sub>1</sub> takes place continuously. We found two such parts in the iGEM distribution kit, and tried to build the construct with both of them.
+For detailed results, see <a href="https://2018.igem.org/Team:ICT-Mumbai/Results"><u>results</u></a> page.
 </p>
+<h4>Promoter induced by transcription activator (P<sub>TA</sub>)</h4>
+<p>P<sub>TA</sub> is the promoter which, when induced by the transcription activator, drives the transcription of the output reporter gene along with transcription activator itself. The promoters which could be activated by Pag or Ogr activators were required for the construct. Two such promoters were chosen from iGEM 2018 Distribution Kit:</p>
 <ol>
-<li>BBa_K274380 (Contains pag activator protein)
+<li>Promoter PF from phage P2 (Part #BBa_I746360)
-<li>BBa_K274371 (Contains ogr activator Protein)
+<li>Promoter PO from phage P2 (Part #BBa_I746361)
 </ol>
+<p>
+As both of these are non-native to the chassis organism, the interference with native gene regulation is not expected.
+</p>
 <h4>Reporter Gene</h4>
 <p>
-Aim of this amplification is to increase the efficiency of phosphate solubilization. The gene PhoD, in the genomic DNA of B subtilis strain 168 codes for the phosphodiasterase, which helps in assimilation of organic phosphorous in the soil. We were able to extract this gene out of the genomic DNA of B subtilis strain 168 by PCR amplification. But decided to use the reporter gene RFP coding device (Part #BBa_K518012), readily available in the iGEM Distribution Kit for characterization of our construct for its ease in quantification.
+The positive feedback circuits leads to the amplification of response to inducers. For the quantification of this response, the reporter gene rfp was selected as the output for its ease in characterization using measurement of fluorescence and easy availability in iGEM 2018 Distribution Kit.
+<br>
+<br>
+Please click <a href="https://2018.igem.org/Team:ICT-Mumbai/Results"><u>here</u></a> for detailed documentation of results.
 </p>
 </div>
 </html>

Difference between revisions of "Team:ICT-Mumbai/Design"