Team:Tianjin/Project/Design

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<center><span style="font-family:Arial;font-size:46px;color:#000;"> Design </span></center>
<center><span style="font-family:Arial;font-size:46px;color:#000;"> Design </span></center>
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<p> To construct a selection module, we need to find a gene circuit which can respond to alkanes, our target products. In nature, many oil-degrading prokaryotes such as <i>P. putida</i> Gpo1, <i>Alcanivorax borkumensis</i> SK2 and <i>Acinetobacter baylyi </i>ADP1 have gene circuits responding to alkanes(alkS-alkB from P. putida Gpo1, alkS-alkB1 from <i>Alcanivorax borkumensis</i> SK2[1], and alkR-PalkM from <i>Acinetobacter baylyi </i>ADP1[2]). We choose the alkR-PalkM circuit in <i>Acinetobacter baylyi</i> ADP1 which has remained untouched in iGEM competition, because this circuit is specifically suitable for alkane synthesis pathway. AlkR responds to a broad range of alkanes with carbon chain length from C7 to C36, and it’s the only bioreporter that is able to detect alkane with carbon chain length greater than C18[2]. Additionally, although fatty alcohol whose structure is similar to alkane can also combine with alkR but their combined compounds will inhibit PalkM.</p>
 
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<p> Alkanes are presumably recognized by alkR and their interaction triggers a conformation change of alkR dimers which leads to the activation of genes downstream of promoter alkM[2].</p>
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= ALKR-PalkM system in the original organism=
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<p> To know more about <i>Acinetobacter baylyi</i> ADP1, alkR protein, and P-alkM promoter, please clike <a href="#anchor-p-08">here</a>.</p>
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<p> To realize the goal of selection, we construct two circuits based on the interaction mechanism of alkR and PalkM.</p>
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<b>Figure 1.</b>&nbsp; Mechanism of ALKR-PalkM system in <i>Acinetobacter baylyi </i>ADP1</div>
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<b>Figure 2.</b>&nbsp; Homologous modeling figure of protein ALKR </div>
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<p> The first circuit is a fluorescent selection circuit. We put the RFP(red fluorescent protein) gene under the regulation of PalkM. When PalkM is induced, downstream RFP gene will express, and red fluorescence of cells can be detected. Therefore, we can transform the alkane molecules into fluorescent output.</p>
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<p> Protein ALKR and promoter alkM are originally found from <i>Acinetobacter baylyi</i> ADP1. The ALKR-PalkM gene circus is part of the regulation system of alkane metabolism.</p>
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<p><i> Acinetobacter </i>sp. are ubiquitous bacteria in natural aquatic and soil environment that are frequently found to be capable to degrade a broad range of carbon chain alkenes and alkanes[3]. And <i>Acinetobacter baylyi</i> ADP1 is able to use long-chain-length alkanes with at least 12 carbon atoms as the sole source of carbon and energy[4]. In <i>Acinetobacter baylyi</i> ADP1, P-alkM is the promoter of alkane hydroxylase genes which encodes alkane hydroxylase(alkM), a crucial enzyme in the degradation of alkanes. AlkM, together with rubredoxin (RubA) and rubredoxin reductase(RubB) forms a three-component alkane monooxygenase complex which oxidate inert alkane to the respective primary alcohol[4]. AlkR is an AraC/XylS-like transcriptional regulatory protein. It includes C-terminal DNA-binding domain for promoter binding and N-terminal domain for inducer recognition[2]. Its function is to recognize alkane molecule after its own dimerization and induce promoter alkM. The activity of alkane hydroxylase could impede ALKR’s function. When alkane molecules occur, they could be recognized by protein ALKR. A three component complex is formed. The inducer complex can bind with promoter alkM and activate the genes in the downstream of PalkM.</p>
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<p> The second circuit is a resistant selection circuit. We get TetA gene from PSB1t3 plasmid and replace RFP gene with TetA gene. TetA will transport tetracycline out of the cell so that the intracellular concentration of tetracycline is relatively stable, and the growth of cells will not be inhibited. Thus, we can turn alkane molecules into the output of the resistance against tetracycline of cells.</p>
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= Our first trail=
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<p> To know more about the transportation mechanism of tetA protein, please click <a href="#anchor-p-09">here</a>.</p>
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<p> The two selection circuits mentioned above can be applied to irrationally modify alkane producing module.</p>
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<p> First method is to combine the strains with an alkane producing module and a fluorescent selection circuit in the medium. Theoretically, the strains with higher alkane yield will have a stronger expression level of RFP. We can select out the high yield strains which have strong fluorescence intensity.</p>
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<p> Our goal is to build a specific alkane sensing device in the cell. The device could sense alkanes and transfer the inconspicuous alkanes to some conspicuous signals, such as some chromophoric or florescent signals. We could place both alkane biosynthesis module and AlkSensor into E coli. The alkane molecules produced by alkane biosynthesis module can be recognised by AlkSensor. And AlkSensor generate a conspicuous signal which can be easily detected.</p>
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<div style="text-align:center;vertical-align:middle;"><a href="#" target="_blank" ><img src="#" width="600px" /></a></div>
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<b>Figure 3.</b>&nbsp; A rough idea of our design </div>
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<p> Another method is to put the strains with an alkane producing module and a resistant selection circuit in the medium of a certain concentration of tetracyclin, hoping that strains with improved alkane productivity will have a stronger capacity to suivive and enrich under this kind of selection pressure. After several rounds of enrichment culturing, we can get strains with high alkane productivity.</p>
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<p> Based on the ALKR-PalkM mechanism in <i>Acinetobacter baylyi</i> ADP1, we designed an alkane sensor in E coli. The sensor is composed of two parts: alkane sensing part and signal generation part. The core of alkane sensing part in <i>Acinetobacter baylyi</i> ADP1 is promoter alkM, so we took PalkM into our design. Besides, PalkM must co-function with transcription factor ALKR, so we constructed ALKR into the sensor. ALKR and PalkM are sufficient for sensing alkanes. The function of signal generation part is to output a conspicuous or easily detectable signal. In this case, we chose RFP as the reporter.</p>
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<p> Our first design is shown in figure 3. We linked ALKR with a constitutive promoter,a strong promoter J23100, and linked RFP with P-alkM. AlkR is followed by a short terminator B1006.The two gene pieces are constructed into plasmid pSB1C3. The inputs of AlkSensor are alkanes and the outputs are RFPs.</p>
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<b>Figure 4.</b>&nbsp; The first version of AlkSensor </div>
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= Introduction of alkR and PalkM=
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= Optimization and our final construction=
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<p> We performed a blank test on the first version of AlkSensor. Without any inducers, AlkSensor still shown significant leakage. We can see from the results that many of the bacterial colonies are red enough to be distinguished by naked eyes.</p>
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<b>Figure 1.</b>&nbsp; Homologous modeling figure of protein ALKR </div>
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<b>Figure 5.</b>&nbsp; The leakage of the first version of AlkSensor is non-ignorable </div>
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<p> Protein ALKR and promoter alkM are originally found from Acinetobacter baylyi ADP1.</p>
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<p> Followings are three possible causes of the leakage.</p>
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<p><i> Acinetobacter</i> sp. are ubiquitous bacteria in natural aquatic and soil environment that are frequently found to be capable to degrade a broad range of carbon chain alkenes and alkanes[3]. And Acinetobacter baylyi ADP1 is able to use long-chain-length alkanes with at least 12 carbon atoms as the sole source of carbon and energy[4].</p>
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<p> a) Promoter alkM has some leakage, to be more specific, it binds to RNA polymerase without undergoing a conformation change and activates the transcription</p>
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<p> In <i>Acinetobacter baylyi </i>ADP1, P-alkM is the promoter of alkane hydroxylase genes which encodes alkane hydroxylase(alkM), a crucial enzyme in the degradation of alkanes. AlkM, together with rubredoxin (RubA) and rubredoxin reductase(RubB) forms a three-component alkane monooxygenase complex which oxidate inert alkane to the respective primary alcohol[4].</p>
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<p> b)Protein ALKR or dimerized ALKR could induce promoter alkM without alkane molecules.</p>
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<p> AlkR is an AraC/XylS-like transcriptional regulatory protein. It includes C-terminal DNA-binding domain for promoter binding and N-terminal domain for inducer recognition[2]. Its function is to recognize alkane molecule after its own dimerization and induce promoter alkM. The activity of alkane hydroxylase could impede ALKR’s function.</p>
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<p> c)The terminator upstream of PalkM is BBa_B1006 which is relatively short (only 34 bp), and it has a weak terminating ability, while the constitutive promoter BBa_J23100 upstream of AlkR is strong, so expression of RFP might be influenced.</p>
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<p> We Reconstruct AlkSensor :</p>
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<p> a) Changed the promoter of ALKR to a weaker promoter.</p>
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<p> b) Switch the position of gene pieces ALKR and PalkM-RFP </p>
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<p> c) Replace terminator B1006 with a stronger terminator, B0015 </p>
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<b>Figure 6.</b>&nbsp; AlkSensor after reconstruction </div>
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<p> Through another blank test we found that the reconstruction could decrease AlkSensor’s leakage significantly. After optimization, the percent of bacterial colonies are red enough to be distinguished by naked eyes decrease from 95% to 15%.</p>
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=Reference=
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<div style="text-align:center;vertical-align:middle;"><a href="#" target="_blank" ><img src="#" width="600px" /></a></div>
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<b>Figure 7.</b>&nbsp; Comparison of two versions of AlkSensor </div>
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<p> We also used full dose octane to induce the two sensors. After a certain period of time of cultivation, the relative fluorescent intensity was measured. The results show that after reconstruction the leakage decreases by 50%, the dynamic range increases by 5 folds, which means that the optimized AlkSensor has stronger ability to distinguish different inputs.</p>
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<p>[1] Rekha Kumari, Robin Tecon, Siham Beggah et al.(2011) “Development of bioreporter assays for the detection of bioavailability of long-chain alkanes based on the marine bacterium <i>Alcanivorax borkumensis</i> strain SK2.” Environmental Microbiology 13(10), 2808–2819</p>
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<p>[2] Zhang, Dayi, et al.(2012) "Whole-cell bacterial bioreporter for actively searching and sensing of alkanes and oil spills." Microbial Biotechnology 5.1: 87-97.</p>
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<b>Figure 8.</b>&nbsp; Octane induce test of two versions of AlkSensor </div>
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<p>[3] Young, David M., Donna Parke, and L. Nicholas Ornston. (2005) "Opportunities for genetic investigation afforded by Acinetobacter baylyi, a nutritionally versatile bacterial species that is highly competent for natural transformation." Annu. Rev. Microbiol. 59: 519-551.</p>
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<p>[4] Ratajczak, Andreas, Walter Geißdörfer, and Wolfgang Hillen. (1998) "Expression of Alkane Hydroxylase fromAcinetobacter sp. Strain ADP1 Is Induced by a Broad Range of n-Alkanes and Requires the Transcriptional Activator ALKR."Journal of bacteriology 180.22: 5822-5827.</p>
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Revision as of 08:57, 17 October 2013

Design

ALKR-PalkM system in the original organism

Figure 1.  Mechanism of ALKR-PalkM system in Acinetobacter baylyi ADP1

Figure 2.  Homologous modeling figure of protein ALKR

Protein ALKR and promoter alkM are originally found from Acinetobacter baylyi ADP1. The ALKR-PalkM gene circus is part of the regulation system of alkane metabolism.

Acinetobacter sp. are ubiquitous bacteria in natural aquatic and soil environment that are frequently found to be capable to degrade a broad range of carbon chain alkenes and alkanes[3]. And Acinetobacter baylyi ADP1 is able to use long-chain-length alkanes with at least 12 carbon atoms as the sole source of carbon and energy[4]. In Acinetobacter baylyi ADP1, P-alkM is the promoter of alkane hydroxylase genes which encodes alkane hydroxylase(alkM), a crucial enzyme in the degradation of alkanes. AlkM, together with rubredoxin (RubA) and rubredoxin reductase(RubB) forms a three-component alkane monooxygenase complex which oxidate inert alkane to the respective primary alcohol[4]. AlkR is an AraC/XylS-like transcriptional regulatory protein. It includes C-terminal DNA-binding domain for promoter binding and N-terminal domain for inducer recognition[2]. Its function is to recognize alkane molecule after its own dimerization and induce promoter alkM. The activity of alkane hydroxylase could impede ALKR’s function. When alkane molecules occur, they could be recognized by protein ALKR. A three component complex is formed. The inducer complex can bind with promoter alkM and activate the genes in the downstream of PalkM.


Our first trail


Our goal is to build a specific alkane sensing device in the cell. The device could sense alkanes and transfer the inconspicuous alkanes to some conspicuous signals, such as some chromophoric or florescent signals. We could place both alkane biosynthesis module and AlkSensor into E coli. The alkane molecules produced by alkane biosynthesis module can be recognised by AlkSensor. And AlkSensor generate a conspicuous signal which can be easily detected.

Figure 3.  A rough idea of our design

Based on the ALKR-PalkM mechanism in Acinetobacter baylyi ADP1, we designed an alkane sensor in E coli. The sensor is composed of two parts: alkane sensing part and signal generation part. The core of alkane sensing part in Acinetobacter baylyi ADP1 is promoter alkM, so we took PalkM into our design. Besides, PalkM must co-function with transcription factor ALKR, so we constructed ALKR into the sensor. ALKR and PalkM are sufficient for sensing alkanes. The function of signal generation part is to output a conspicuous or easily detectable signal. In this case, we chose RFP as the reporter.

Our first design is shown in figure 3. We linked ALKR with a constitutive promoter,a strong promoter J23100, and linked RFP with P-alkM. AlkR is followed by a short terminator B1006.The two gene pieces are constructed into plasmid pSB1C3. The inputs of AlkSensor are alkanes and the outputs are RFPs.


Figure 4.  The first version of AlkSensor

Optimization and our final construction


We performed a blank test on the first version of AlkSensor. Without any inducers, AlkSensor still shown significant leakage. We can see from the results that many of the bacterial colonies are red enough to be distinguished by naked eyes.


Figure 5.  The leakage of the first version of AlkSensor is non-ignorable

Followings are three possible causes of the leakage.

a) Promoter alkM has some leakage, to be more specific, it binds to RNA polymerase without undergoing a conformation change and activates the transcription

b)Protein ALKR or dimerized ALKR could induce promoter alkM without alkane molecules.

c)The terminator upstream of PalkM is BBa_B1006 which is relatively short (only 34 bp), and it has a weak terminating ability, while the constitutive promoter BBa_J23100 upstream of AlkR is strong, so expression of RFP might be influenced.


We Reconstruct AlkSensor :

a) Changed the promoter of ALKR to a weaker promoter.

b) Switch the position of gene pieces ALKR and PalkM-RFP

c) Replace terminator B1006 with a stronger terminator, B0015


Figure 6.  AlkSensor after reconstruction

Through another blank test we found that the reconstruction could decrease AlkSensor’s leakage significantly. After optimization, the percent of bacterial colonies are red enough to be distinguished by naked eyes decrease from 95% to 15%.


Figure 7.  Comparison of two versions of AlkSensor

We also used full dose octane to induce the two sensors. After a certain period of time of cultivation, the relative fluorescent intensity was measured. The results show that after reconstruction the leakage decreases by 50%, the dynamic range increases by 5 folds, which means that the optimized AlkSensor has stronger ability to distinguish different inputs.


Figure 8.  Octane induce test of two versions of AlkSensor

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