Difference between revisions of "Part:BBa K2240000"

 
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<partinfo>BBa_K2240000 short</partinfo>
 
<partinfo>BBa_K2240000 short</partinfo>
  
<p>This part can detect the deliberately released stimulus so as to initiate the process of 'knockout'. Considering that the released stimulus can be diluted in an environment, a positive feedback loop is introduced to amplify the signal. 3OC6HSL, which is a member of acyl-homoserine lactone (AHL) family, would be the inducer. 3OC6HSL originated from <i>V. fischeri</i> is a lipid molecule that can diffuse through bacterial cell membrane to facilitate the cell-to-cell communication.</p>
+
<p>This part can detect the deliberately released stimulus to initiate the process of 'knockout'. Considering the released stimulus can be diluted in an environment, a positive feedback loop is introduced to amplify the signal. 3OC6HSL, which is a member of acyl-homoserine lactone (AHL) family, is the inducer that is originated from <i>V. fischeri</i>, a lipid molecule that can diffuse across the bacterial cell membrane to facilitate cell-cell communication.</p>
  
<p>This part begins with the TetR repressible promoter (BBa_R0040), which can act as a constitutive promoter of the downstream protein - LuxR (BBa_C0062) under the absence of repressor TetR. Once the 3OC6HSL is added, LuxR will form a complex with 3OC6HSL and then activates the downstream promoter, P<i><sub>luxR</sub></i> (BBa_R0062). In the end, the production of LuxR can be boost, allowing the accumulation the LuxR. </p>
+
<p>This part begins with the <i>TetR</i> repressible promoter (BBa_R0040), which can act as a constitutive promoter to activate LuxR (BBa_C0062) under the absence of repressor TetR. Once 3OC6HSL is added, LuxR will form a complex with 3OC6HSL and then activate the downstream promoter, P<i><sub>luxR</sub></i> (BBa_R0062). In the end, the production of LuxR can be boosted by the accumulation of LuxR. </p>
  
<p>After the activation of P<i><sub>luxR</sub></i>, the autoinducer synthetase (BBa_C0061) would catalyze 3OC6HSL, which woild bind to LuxR, from S-adenosyl-L-methionine (SAM) in cell. Due to the increase of the 3OC6HSL/LuxR complex, the entire part starting from P<i><sub>tetR</sub></i> to LuxI generates positive feedback loop, hence further induces the P<i><sub>luxR</sub></i>. Apart from this, the 3OC6HSL molecule can also diffuse to the extracellular environment and induce the cells nearby.</p>
+
<p>After the activation of P<i><sub>luxR</sub></i>, autoinducer synthetase (BBa_C0061) would synthesize 3OC6HSL, which then bind to LuxR, from S-adenosyl-L-methionine (SAM) in cell. Due to the increase of the 3OC6HSL/LuxR complex, the entire part starting from P<i><sub>tetR</sub></i> to LuxI generates a positive feedback loop, hence, this further induces P<i><sub>luxR</sub></i>. Apart from this, 3OC6HSL can also diffuse to the extracellular environment and induce the nearby cells.</p>
  
<p>Owing to the positive feedback loop, this part would start contributing to signal emission whenever it receives 3OC6HSL molecules. As a result, it is expected to elevate the efficiency of activation under induction.</p>
+
<p>Owing to the positive feedback loop, this part starts emitting signals whenever it receives 3OC6HSL molecules. As a result, it is expected to elevate the activation level under induction.</p>
  
<p>Considering the difficulties that previous iGEM team encountered - the leakiness of P<i><sub>luxR</sub></i> (See experience in <bbpart>BBa_F2620</bbpart>), we tried to get rid of this by adding antisense RNA Binding regions and antisense RNA (asRNA), interaction of which, could counteract the activity of basal level. Ideally, this could help tackling the thorny issue via degrading the mRNA of the downstream proteins.</p>
+
<p>Considering the difficulties encountered by the previous iGEM teams, which was the leakiness of P<i><sub>luxR</sub></i> (See experience in <bbpart>BBa_F2620</bbpart>), we tried to get rid of this by adding antisense RNA binding regions and antisense RNA (asRNA), which could lower basal level. Ideally, it helps tackle this thorny issue.</p>
 
<br>
 
<br>
  
 
===Usage & Biology===
 
===Usage & Biology===
<p>The antisense RNA (asRNA) we used had two important characteristics which might help boost the efficiency in reducing leakiness: possessing the sequence complementary to the of mRNA of ABR, and a Hfq (RNA binding protein) binding site. The affiliation of asRNA to the complementary ABR would prevent ribosome from binding to the mRNA of the targeted RBS. Meanwhile, the presence of a Hfq binding site would help reduce the translation of the 3OC6HSL/LuxR complex since Hfq binding site was suspected to recruit RNase to degrade the targeted RNA chain. With these two effects, the leakiness of P<i><sub>luxR</sub></i> could be lowered.</p>
+
<p>The antisense RNA (asRNA) has two important characteristics which boost the efficiency in reducing leakiness: the sequence complementary to the mRNA of ABR, and a Hfq (RNA binding protein) binding site. The affiliation of asRNA to the complementary ABR can prevent ribosome from binding to the mRNA of the targeted RBS. Meanwhile, the Hfq binding site helps reduce the translation of the 3OC6HSL/LuxR complex since Hfq binding site could recruit RNase to degrade the targeted RNA chain (Hoynes-O’Connor & Moon, 2016). With these two effects, the leakiness of P<i><sub>luxR</sub></i> is lowered.</p>
  
<p>There are two asRNA binding regions (ABR) in total. One is placed right before the targeted ribosomal binding site (RBS), which is upstream of the LuxI (BBa_C0061) and GFP (BBa_E0040) while another one is placed downstream of the positive feedback loop.</p>
+
<p>There are two asRNAs binding regions (ABR) in total. One is placed right before the targeted ribosomal binding site (RBS), which is upstream of the autoinducer synthetase for AHL (BBa_C0061) and GFP generator (BBa_E0240).</p>
  
<p>Under the presence of the 3OC6HSL, 3OC6HSL/LuxR complex could repress P<i><sub>luxL</sub></i>, reducing the production of the asRNA, increasing the production of mRNA of LuxI. This meant that the maximum level of LuxI translation could be reached after 3OC6HSL induction.</p>
+
<p>Under the presence of 3OC6HSL, 3OC6HSL/LuxR complex can repress P<i><sub>luxL</sub></i>, reducing the production of the asRNA, in turn, increasing the production of LuxI. It means that the maximum level of LuxI translation can be achieved after 3OC6HSL induction.</p>
  
<p>Based on the above reasons, it is expected that the ability in sensing the overall population would become more sensitive due to the positive feedback loop, whereas the leakiness could be reduced without the presence of inducer.</p>
+
<p>Based on the reasons above, it is expected that the system would become more sensitive due to the positive feedback loop, whereas the promoter leakiness could also be reduced.</p>
  
 
<br>
 
<br>
 
 
===Antisense RNA Type 1 & 2===
 
===Antisense RNA Type 1 & 2===
To provide an alternative, two antisense RNA sequences (type 1 and type 2) with a few base pairs different were designed for degrading the mRNA. Both of them were obtained from the paper, Development of design rules for reliable asRNA behavior in <i>E. coli</i>, and then slightly modified. Being incorporated into an inducible system with positive feedback loop (PFB) that was able to produce GFP expression, they could be evaluated for their efficiency in reducing the basal level via measuring the GFP output with the presence of AHL.  
+
To provide an alternative of antisense RNA, two antisense RNA sequences (type 1 and type 2) with a few base pairs differences were designed. Both of them were obtained from a journal and they were then slightly modified (Hoynes-O’Connor & Moon, 2016). Being incorporated into an inducible system with positive feedback loop (PFB) that can produce GFP, the efficiency in reducing the basal level can be evaluated via measuring the GFP output under the presence of AHL.
 
<br>
 
<br>
  
<h5>Results</h5>
+
<u><h4>Results</h4></u>
[[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA II without induction.jpeg|thumb|250px|left|<b>Fig.1 Error bar presents SD from 6 biological replicates. </b>]][[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA II with induction.jpeg|thumb|250px|left|<b>Fig.2 Error bar presents SD from 6 biological replicates. </b>]]
+
[[File:Team--Hong Kong HKUST--2 Efficiency of basal level reduction by anti RNAs wo induction.pngduction.jpeg|thumb|420px|left|<b>Fig.1 Error bar presents SD from 6 biological replicates. </b>]][[File:Team--Hong Kong HKUST--3 Efficiency of basal level reduction by anti RNAs with induction.pngduction.jpeg|thumb|430px|right|<b>Fig.2 Error bar presents SD from 6 biological replicates. </b>]]
  
 
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<br><br><br>
 
<br><br><br>
 
<br><br><br>
<h5>1. Antisense RNA (asRNA) can reduce basal expression level</h5>
 
The efficiency of basal level reduction for asRNA type I and II were compared with the control (w/PFB) prior to AHL induction ([AHL]=0M) and after the induction ([AHL]=1.00E-05 M). Unpaired t-test analysis suggested that their differences could be considered as highly statistically significant.
 
 
<br>
 
<h5>2. Antisense RNA type II reduces basal level more significantly</h5>
 
Based on the results obtained from the unpaired t-test calculation, there were significant differences between antisense RNA type I and type II under both cases - before and after AHL induction (1.00E-05 M). Fig.1 and 2 implied that construct with asRNA type II could reduce basal expression level more significant than asRNA type I. This may be due to higher GC content of its complementary sites (55% for asRNA type II comparing to 47.4% for asRNA type I).
 
 
 
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<br><br><br>
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<br><br><br>
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<br><br><br>
  
 +
<p>
 +
<h4>Constructs involved</h4>
 +
<ol>
 +
<li>w/o PFB (without positive feedback loop): pSB1C3-BBa_T9002</li>
 +
<li>w/ PFB (with positive feedback loop): pSB1C3-BBa_F2620-C0261-E0240</li>
 +
<li>PFB + asRNA1: pSB1C3-BBa_K2240000</li>
 +
<li>PFB + asRNA2: pSB1C3-<bbpart>BBa_K2240003</bbpart></li>
 +
</ol>
 +
 +
<h4>Finding 1. Antisense RNA (asRNA) can reduce basal expression level</h4>
 +
The effectiveness of basal level reduction for asRNA type I and II was compared with the control (w/PFB) prior to AHL induction ([AHL]=0M) and after the induction ([AHL]=1.00E-05 M). Unpaired t-test analysis suggested that their differences were statistically significant. Therefore, the two asRNAs could lower the basal level of the targeted promoter.
 +
 +
<h4>Finding 2. Antisense RNA type II reduces basal level more significantly</h4>
 +
Based on the results obtained from the unpaired t-test calculation, there were significant differences between antisense RNA type I and type II under both conditions - before and after AHL induction (1.00E-05 M). Fig.1 and 2 implied that the construct with asRNA type II could reduce basal expression level more significantly than asRNA type I. It was conjectured that this might be caused by the GC content difference in their complementary sites (55% for asRNA type II comparing to 47.4% for asRNA type I) since the two asRNAs only differed in their GC content and sequences.
 +
</p>
 +
 +
<br>
 
===Signal Amplification===
 
===Signal Amplification===
GFP was measured in order to examine the efficiency for the positive feedback loop to amplify the signals with the presence of the antisense RNA.  
+
GFP expression was measured in order to examine the efficiency for the positive feedback loop to amplify the signals with the presence of AHL inducer.  
 
<br>
 
<br>
  
<h5>Results</h5>
+
<u><h4>Results</h4></u>
[[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA I.png|thumb|250px|left|<b>Fig.3 Error bar presents SD from 6 biological replicates. </b>]][[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA II.jpeg|thumb|250px|left|<b>Fig.4 Error bar presents SD from 6 biological replicates. </b>]]
+
[[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA I.png|thumb|430px|left|<b>Fig.3 Error bar presents SD from 6 biological replicates. </b>]][[File:Team--Hong Kong HKUST--Efficiency of basal level reduction by anti RNA II.jpeg|thumb|432px|right|<b>Fig.4 Error bar presents SD from 6 biological replicates. </b>]]
  
 
<br><br><br>
 
<br><br><br>
<h5>3. Positive Feedback Loop works after AHL induction</h5>
+
<br><br><br>
There were also notable statistical differences when comparing the changes before and after induction using two-tailed paired t-test analysis for both PFB+asRNA1 (p<0.001) and PFB+asRNA2 (p<0.01). The average of fluorescence/OD600 for PFB+asRNA2 was 4,199.18 while the average after its induction was 6,121.58, showing an increase for around 2,000 GFP/OD600 (45.8% growth) after 3 hours. Meanwhile, PFB+asRNA1 also experienced an increase by 4,765 GFP/OD600  (65.7% growth) under the same period of time (Fig.5), suggesting that asRNA could regulate translation inhibition more tightly. This showed that there should be an increase in expression after induction by AHL.
+
<br><br><br>
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+
<br><br><br>
 +
<br><br><br>
 +
<br><br><br>
 +
<br><br>
  
 +
<p>
 +
<h4>Finding 3. Positive feedback loop works after AHL induction</h4>
 +
There was also notable statistical differences when comparing the changes before and after induction using the two-tailed paired t-test analysis for both PFB+asRNA1 (p<0.001) and PFB+asRNA2 (p<0.01). Though the calculations are not shown here, the average of fluorescence/OD600 for PFB+asRNA2 was 4,199.18 while the average after its induction was 6,121.58, showing an increase for 1,922.4 GFP/OD600 (45.8% growth) after 3 hours. On the other hand, PFB+asRNA1 also experienced an increase by 4,765 GFP/OD600  (65.7% growth) under the same condition (Fig.4). An increase in expression after the AHL induction suggests that asRNA could work as expected.
 +
<br>
 +
</p>
  
<br><br>
+
<br>
 
===Conclusions from the Experiments===
 
===Conclusions from the Experiments===
 
The antisense RNAs construct can verify the following hypotheses:
 
The antisense RNAs construct can verify the following hypotheses:
<p>1. There was a significant decrease in basal expression level when antisense RNA type I and II were used.</p>
+
<p>1. There was a significant decrease in basal level when antisense RNA type I and II were incorporated into the system.</p>
<p>2. Antisense RNA type II reduced basal level expression more efficiently than antisense RNA type I.</p>
+
<p>2. Antisense RNA type II reduced basal level more effective than antisense RNA type I.</p>
<p>3. Positive feedback loop remained functional after being activated by 1.00E-05 M of AHL after 3 hours.</p>
+
<p>3. The positive feedback loop was functional.</p>
  
<br><br><br>
 
<br><br><br>
 
  
 +
<br>
 
<!-- Add more about the biology of this part here
 
<!-- Add more about the biology of this part here
 
===Usage and Biology===
 
===Usage and Biology===

Latest revision as of 01:47, 5 December 2017


AHL sensor with positive feedback loop, GFP output and antisense RNA type 1 inhibition

This part can detect the deliberately released stimulus to initiate the process of 'knockout'. Considering the released stimulus can be diluted in an environment, a positive feedback loop is introduced to amplify the signal. 3OC6HSL, which is a member of acyl-homoserine lactone (AHL) family, is the inducer that is originated from V. fischeri, a lipid molecule that can diffuse across the bacterial cell membrane to facilitate cell-cell communication.

This part begins with the TetR repressible promoter (BBa_R0040), which can act as a constitutive promoter to activate LuxR (BBa_C0062) under the absence of repressor TetR. Once 3OC6HSL is added, LuxR will form a complex with 3OC6HSL and then activate the downstream promoter, PluxR (BBa_R0062). In the end, the production of LuxR can be boosted by the accumulation of LuxR.

After the activation of PluxR, autoinducer synthetase (BBa_C0061) would synthesize 3OC6HSL, which then bind to LuxR, from S-adenosyl-L-methionine (SAM) in cell. Due to the increase of the 3OC6HSL/LuxR complex, the entire part starting from PtetR to LuxI generates a positive feedback loop, hence, this further induces PluxR. Apart from this, 3OC6HSL can also diffuse to the extracellular environment and induce the nearby cells.

Owing to the positive feedback loop, this part starts emitting signals whenever it receives 3OC6HSL molecules. As a result, it is expected to elevate the activation level under induction.

Considering the difficulties encountered by the previous iGEM teams, which was the leakiness of PluxR (See experience in BBa_F2620), we tried to get rid of this by adding antisense RNA binding regions and antisense RNA (asRNA), which could lower basal level. Ideally, it helps tackle this thorny issue.


Usage & Biology

The antisense RNA (asRNA) has two important characteristics which boost the efficiency in reducing leakiness: the sequence complementary to the mRNA of ABR, and a Hfq (RNA binding protein) binding site. The affiliation of asRNA to the complementary ABR can prevent ribosome from binding to the mRNA of the targeted RBS. Meanwhile, the Hfq binding site helps reduce the translation of the 3OC6HSL/LuxR complex since Hfq binding site could recruit RNase to degrade the targeted RNA chain (Hoynes-O’Connor & Moon, 2016). With these two effects, the leakiness of PluxR is lowered.

There are two asRNAs binding regions (ABR) in total. One is placed right before the targeted ribosomal binding site (RBS), which is upstream of the autoinducer synthetase for AHL (BBa_C0061) and GFP generator (BBa_E0240).

Under the presence of 3OC6HSL, 3OC6HSL/LuxR complex can repress PluxL, reducing the production of the asRNA, in turn, increasing the production of LuxI. It means that the maximum level of LuxI translation can be achieved after 3OC6HSL induction.

Based on the reasons above, it is expected that the system would become more sensitive due to the positive feedback loop, whereas the promoter leakiness could also be reduced.


Antisense RNA Type 1 & 2

To provide an alternative of antisense RNA, two antisense RNA sequences (type 1 and type 2) with a few base pairs differences were designed. Both of them were obtained from a journal and they were then slightly modified (Hoynes-O’Connor & Moon, 2016). Being incorporated into an inducible system with positive feedback loop (PFB) that can produce GFP, the efficiency in reducing the basal level can be evaluated via measuring the GFP output under the presence of AHL.

Results

Fig.1 Error bar presents SD from 6 biological replicates.
Fig.2 Error bar presents SD from 6 biological replicates.

























Constructs involved

  1. w/o PFB (without positive feedback loop): pSB1C3-BBa_T9002
  2. w/ PFB (with positive feedback loop): pSB1C3-BBa_F2620-C0261-E0240
  3. PFB + asRNA1: pSB1C3-BBa_K2240000
  4. PFB + asRNA2: pSB1C3-BBa_K2240003

Finding 1. Antisense RNA (asRNA) can reduce basal expression level

The effectiveness of basal level reduction for asRNA type I and II was compared with the control (w/PFB) prior to AHL induction ([AHL]=0M) and after the induction ([AHL]=1.00E-05 M). Unpaired t-test analysis suggested that their differences were statistically significant. Therefore, the two asRNAs could lower the basal level of the targeted promoter.

Finding 2. Antisense RNA type II reduces basal level more significantly

Based on the results obtained from the unpaired t-test calculation, there were significant differences between antisense RNA type I and type II under both conditions - before and after AHL induction (1.00E-05 M). Fig.1 and 2 implied that the construct with asRNA type II could reduce basal expression level more significantly than asRNA type I. It was conjectured that this might be caused by the GC content difference in their complementary sites (55% for asRNA type II comparing to 47.4% for asRNA type I) since the two asRNAs only differed in their GC content and sequences.


Signal Amplification

GFP expression was measured in order to examine the efficiency for the positive feedback loop to amplify the signals with the presence of AHL inducer.

Results

Fig.3 Error bar presents SD from 6 biological replicates.
Fig.4 Error bar presents SD from 6 biological replicates.





















Finding 3. Positive feedback loop works after AHL induction

There was also notable statistical differences when comparing the changes before and after induction using the two-tailed paired t-test analysis for both PFB+asRNA1 (p<0.001) and PFB+asRNA2 (p<0.01). Though the calculations are not shown here, the average of fluorescence/OD600 for PFB+asRNA2 was 4,199.18 while the average after its induction was 6,121.58, showing an increase for 1,922.4 GFP/OD600 (45.8% growth) after 3 hours. On the other hand, PFB+asRNA1 also experienced an increase by 4,765 GFP/OD600 (65.7% growth) under the same condition (Fig.4). An increase in expression after the AHL induction suggests that asRNA could work as expected.


Conclusions from the Experiments

The antisense RNAs construct can verify the following hypotheses:

1. There was a significant decrease in basal level when antisense RNA type I and II were incorporated into the system.

2. Antisense RNA type II reduced basal level more effective than antisense RNA type I.

3. The positive feedback loop was functional.



Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 1751
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI.rc site found at 1004
    Illegal BsaI.rc site found at 2455
    Illegal BsaI.rc site found at 2674